Direct cooling of clathrate flowing in a pipeline system

What is claimed is: 1. A pipeline system comprising: a transportation conduit containing a gas hydrate flowing from a first geographical location to another geographical location; and a cooling system including a cooling conduit, the transportation conduit being disposed exterior to the cooling conduit, the cooling system being in thermal contact with the flowing gas hydrate and maintaining the temperature of the flowing gas hydrate within a target temperature range predicted to maintain a selected stability of the flowing gas hydrate, the cooling system including a closed-cycle cooling system that includes a refrigeration system powered by combustion of gas released by decomposition of the flowing gas hydrate. 2. The pipeline system of claim 1 , wherein the gas hydrate includes a natural gas hydrate. 3. The pipeline system of claim 1 , wherein the gas hydrate includes a CO 2 gas hydrate. 4. The pipeline system of claim 1 , wherein the transportation conduit contains the flowing gas hydrate at a low pressure. 5. The pipeline system of claim 1 , wherein the transportation conduit contains the flowing gas hydrate at a pressure less than 20 bars. 6. The pipeline system of claim 1 , wherein the transportation conduit contains the flowing gas hydrate at a pressure less than 5 bars. 7. The pipeline system of claim 1 , wherein the transportation conduit includes a metal or plastic material. 8. The pipeline system of claim 1 , wherein the cooling system includes an evaporator portion composing a portion of the cooling conduit in thermal contact with the flowing gas hydrate. 9. The pipeline system of claim 8 , wherein the evaporator portion is located within the transportation conduit and in direct thermal contact with the flowing gas hydrate. 10. The pipeline system of claim 8 , wherein the evaporator portion has an indirect thermal contact with the flowing gas hydrate. 11. The pipeline system of claim 1 , wherein at least a portion of a wall of the transportation conduit is disposed between the flowing gas hydrate and an evaporator portion composing a portion of the cooling conduit of the cooling system. 12. The pipeline system of claim 11 , wherein at least the portion of the wall of the transportation conduit has a thermal conductivity of k>30 W/(m*K). 13. The pipeline system of claim 11 , wherein at least the portion of the wall of the transportation conduit has a thermal conductivity of k>70 W/(m*K). 14. The pipeline system of claim 1 , wherein an evaporator portion composing a portion of the cooling conduit of the cooling system is positioned at a potential hot spot of the transportation conduit. 15. The pipeline system of claim 1 , further comprising: a pump system urging the flowing gas hydrate through at least a portion of the transportation conduit. 16. The pipeline system of claim 15 , wherein the pump system is powered by combustion of gas decomposed from the flowing gas hydrate transported in the transportation conduit. 17. The pipeline system of claim 1 , further comprising: a pressure sensor responsive to a pressure of the flowing gas hydrate. 18. The pipeline system of claim 1 , further comprising: a temperature sensor responsive to a temperature of the flowing gas hydrate. 19. The pipeline system of claim 1 , further comprising: a controller configured to control a pressure or temperature of the flowing gas hydrate in response to a sensed pressure or temperature of the flowing gas hydrate. 20. A method implemented in a transportation pipeline system, the method comprising: flowing a natural gas hydrate from a first geographical location to another geographical location through a transportation conduit of the pipeline system; flowing a heat-transfer fluid between the first geographic location and the second geographic location through a cooling conduit of the pipeline system, the transportation conduit being disposed exterior to the cooling conduit; and maintaining the flowable natural gas hydrate within a target temperature range during its transit of a portion of the pipeline system using refrigeration powered by combustion of natural gas decomposed from the flowable natural gas hydrate transiting the portion of the pipeline system, the target temperature range predicted to provide a selected stability of the flowable natural gas during its transit of the portion of the pipeline system. 21. The method of claim 20 , wherein the refrigeration is powered at least in part by combustion of natural gas released by decomposition of the flowable natural gas hydrate occurring in the normal course of transiting the portion of the pipeline system. 22. The method of claim 20 , wherein the refrigeration is powered at least in part by combustion of natural gas intentionally withdrawn and decomposed from the natural gas hydrate transiting the portion of the pipeline system. 23. The method of claim 20 , wherein the target temperature range provides a selected flowability of the natural gas hydrate, and is at least partially based on the stability temperature and pressure phase relationship for the particular natural gas hydrate transiting the portion of the pipeline system.