Passive safety system for removing decay heat and method of passively increasing a coolant flow using the same

The invention claimed is: 1. A passive safety system for removing heat from a nuclear power system, comprising: a shroud structure including a body portion and an upper portion, the upper portion including an outlet opening; a steam generator within the body portion of the shroud structure, an inner surface of the body portion of the shroud structure and an outer surface of the steam generator defining a coolant passage therebetween, the coolant passage being in fluidic communication with the outlet opening; a thermoelectric device disposed in the coolant passage and in thermal contact with the steam generator, the thermoelectric device configured to generate a voltage based on a temperature difference between opposite parts of the thermoelectric device, the thermoelectric device being a sheet-like article having a heat absorption side and an opposing heat rejection side, the heat absorption side facing the outer surface of the steam generator, the heat rejection side facing the inner surface of the shroud structure; and a fan arrangement disposed above the steam generator and in electrical connection with the thermoelectric device, the fan arrangement configured to increase a coolant flow through the coolant passage to the outlet opening based on the voltage from the thermoelectric device. 2. The passive safety system of claim 1 , wherein the nuclear power system is a liquid metal cooled reactor. 3. The passive safety system of claim 1 , wherein the thermoelectric device is closer to the steam generator than the shroud structure. 4. The passive safety system of claim 1 , wherein the thermoelectric device is at a distance of about 3 inches or less from the steam generator. 5. The passive safety system of claim 1 , wherein the thermoelectric device has a thickness that is less than half of a spacing distance between the steam generator and the shroud structure. 6. The passive safety system of claim 1 , wherein the thermoelectric device is conformally-shaped to follow contours of the steam generator. 7. The passive safety system of claim 1 , wherein the thermoelectric device is closer to a top of the steam generator than a bottom of the steam generator. 8. The passive safety system of claim 1 , wherein the thermoelectric device surrounds at least 25% of a side surface of the steam generator. 9. The passive safety system of claim 1 , wherein the thermoelectric device includes a concave side and an opposing convex side, the concave side being the heat absorption side, the convex side being the heat rejection side. 10. The passive safety system of claim 1 , wherein the thermoelectric device is disposed circumferentially around the steam generator. 11. The passive safety system of claim 1 , wherein the thermoelectric device is in a form of a plurality of thermoelectric generators surrounding the steam generator. 12. The passive safety system of claim 11 , wherein each of the plurality of thermoelectric generators is electrically connected to jointly power the fan arrangement with the voltage. 13. The passive safety system of claim 11 , wherein one of the plurality of thermoelectric generators is a primary source of the voltage, and another of the plurality of thermoelectric generators is a backup source of the voltage. 14. The passive safety system of claim 11 , wherein the fan arrangement is in a form of a plurality of fans, each of the plurality of thermoelectric generators being electrically connected to one of the plurality of fans. 15. The passive safety system of claim 1 , wherein the fan arrangement is disposed in the upper portion of the shroud structure below the outlet opening. 16. A method of passively increasing a coolant flow in a natural circulation decay heat removal system, comprising: arranging a thermoelectric device so as to be in electrical connection with a fan arrangement and so as to be within a coolant passage for the coolant flow, the coolant passage defined by an inner surface of a shroud structure and an outer surface of a steam generator, the shroud structure including a body portion and an upper portion, the upper portion including an outlet opening, the steam generator within the body portion of the shroud structure, an inner surface of the body portion of the shroud structure and the outer surface of the steam generator defining the coolant passage therebetween, the coolant passage being in fluidic communication with the outlet opening, the thermoelectric device in thermal contact with the steam generator, the thermoelectric device configured to generate a voltage based on a temperature difference between opposite parts of the thermoelectric device, the thermoelectric device being a sheet-like article having a heat absorption side and an opposing heat rejection side, the heat absorption side facing the outer surface of the steam generator, the heat rejection side facing the inner surface of the shroud structure, the fan arrangement disposed above the steam generator and configured to increase the coolant flow through the coolant passage to the outlet opening based on the voltage from the thermoelectric device; and supplying the voltage to the fan arrangement from the thermoelectric device based on the temperature difference caused by the steam generator in order to increase the coolant flow. 17. The method of claim 16 , wherein the supplying is based on the temperature difference between opposite parts of the thermoelectric device being at least 30 degrees Celsius. 18. The method of claim 16 , wherein the supplying is such that the voltage is at least 12 volts. 19. The method of claim 16 , wherein the supplying is such that a discharge velocity of the coolant flow is increased to at least 80 feet/second. 20. The method of claim 16 , wherein the supplying occurs during a scheduled or emergency shutdown of a nuclear power system.