Patent Number: 046876260
Section: description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides a safety device for dumping steam from a steam generator in a nuclear power reactor, removing residual heat from the steam generator and providing the steam generator with feedwater during emergencies such as steam line rupture and/or power failure. As shown in FIG. 1, reference numeral 10 generally refers to the safety device of the present invention which is located outside the containment wall 12 for steam generator 14 which is connected to a nuclear power reactor (not shown). Steam from generator 14 is fed through valve 16 and containment wall 12 to drive steam turbines (not shown) via main steam line 18. Outside containment wall 12, main steam line 18 is provided with steam safety valve 20. Downsteam from safety valve 20, steam isolation valve 22 is provided on main steam line 18. Between valves 18 and 22, branch pipe 24 feeds steam in main steam line 18 into cold water storage tank 26 through steam relief valve 28. The lower end of line 24 is formed into a nozzle or steam jet 30 for the ejection of high pressure steam into diffuser body 32. Inlet 34 of diffuser body 32 is in the form of an inverted bell for the suction of cold water in storage tank 26 into diffuser body 32. Discharge 34 of diffuser body 32 is in fluid communication with chamber 36 where the condensed steam in the form of a subcooled water is stored. Chamber 36 is provided with exit 38 which is connected to the entrance 40 of a heat exchange device. Typically, the heat exchange device is a cooling coil 42 which provides a large surface area for optimal heat transfer. The outlet 44 of cooling coil 42 is connected to inlet port 46 in storage tank 26. Thus, hot steam condensatae flows from chamber 36 through outlet 38 and inlet 40 into cooling coil 42, leaves the coil through outlet 44 and into storage tank 26. To prevent excessive build-up of cooling water in storage tank 26, a drain pipe controlled by valve 29 is provided in storage tank 26. Cooling coil 42 is submerged in cold water storage tank 50 for heat exchange between the hot condensate within the coil and the cold water stored in pool 46. The volume of coolant water stored in pool 46 should be sufficiently large so as to allow optimal cooling of the coil 42. In a preferred embodiment, pool 46 is in the shape of an inverted L, i.e. one comprising a horizontal portion 48 and vertical portion 50. In FIG. 1, cooling coil 42 is placed within the vertical section in pool 50 which is divided into two connecting chambers by baffle 52. Baffle 52 comprises a long vertical section 51, a short vertical section 53 and a horizontal section 55 connecting the two vertical sections 51 and 53. Baffle 52 is completely under the waterline in pool 46. The baffle forms two chambers 54 and 56 in pool 46 which are in fluid communication. Cooling coil 42 is placed in the vertical portion of chamber 56. In order to permit device 10 to function as an emergency feedwater source to steam generator 14, chamber 36 is optionally connected to main feedwater line 15 to steam generator 14 via pipe 58 and exit 60. Emergency feedwater valve 62 is located downstream from exit 60 in pipe 58. Check valves 64 prevent the flow of feedwater from line 15 into chamber 36. Emergency feedwater valve 62 is opened when the pressure within chamber 36 exceeds a specified limit. In operation, when there is a rupture in the main steam line downstream from steam isolation valve 22, valve 22 is closed to direct the flow of steam into device 10 of the present invention. When the pressure within line 18 exceeds a specific value, steam relief valve 28 opens, thus allowing high pressure steam to flow through nozzle 30 as a strong steam jet. The flow of the steam from nozzle 30 into diffuser body 32 causes cold water in storage tank 26 to be entrained and drawn into diffuser body 32. The steam is condensed and is collected in chamber 36 as subcooled water. As more steam enters diffuser body 32, the condensate is forced into inlet 40 of cooling coil 42 submerged in cooling water pool 48. The condensate flows up coil 42, through outlet 44 and inlet 46 into storage tank 26. Heat in the condensate is dissipated to the cooling water in chamber 56 of pool 54. As a result, when the condensate enters storage tank 26, its temperature is much lower than the condensate in chamber 36. Due to the transfer of heat into chamber 56, the water therein rises as a result of the increase in temperature. Consequently, the water in pool 48 is caused to circulate by flowing upwardly and then horizontally in chamber 56 over short vertical section of baffle 53 into chamber 54 where it flows horizontally and then vertically down past the lower end of long vertical section 51 of baffle 52 into chamber 56. Due to this circulation, the cooling water loses the heat it absorbs from cooling coil 42 so that when the water enters chamber 56, the temperature of the water has dropped significantly and can be used to absorb heat from cooling. coil 42 again. Accordingly, the steam from main steam line 18 can be safely dumped into safety device 10, a closed system, without the risk of harming the surrounding atmosphere. In addition, the residual heat in the steam generator can be dissipated through device 10 which requires no power source to operate, i.e. a passive system. Hence, in the event of a total alternating current power failure, the present safety device 10 offers a back-up cooling system which will operate without power. Valves 20, 22, 24 and 62 can be pressure-operated or direct current operated so as to render device totally independent of alternating current power. The present device can also provide emergency feedwater to the steam generator. When the pressure in chamber 36 exceeds a specified value, valve 62 opens, thus allowing the condensate stored therein to flow through check valves 64 and pipe 15 and into steam generator 14 as feedwater.