REVERSE STEAM GENERATOR FOR A LEAD-COOLED FAST REACTOR

Abstract

Reverse steam generator for a lead-cooled fast reactor. The reverse steam generator comprises a cylindrical body with a bundle of heat exchange tubes located inside, the ends of the heat exchange tubes being fixed in tube sheets with intermediate support grids; inlet and outlet spherical chambers for supplying liquid metal coolant; a lower branch pipe for inlet water; and an upper branch pipe for a steam outlet. The cylindrical body is arranged horizontally and is curved in a Z-shape with a difference in height. The bundle of heat exchange tubes is also made in a Z-shape, repeating the bend of the cylindrical body.

Claims

1. A reverse steam generator for a lead-cooled fast reactor, a cylindrical body with a bundle of heat exchange tubes located inside, the ends of the heat exchange tubes being fixed in tube sheets with intermediate support grids; inlet and outlet spherical chambers for supplying liquid metal coolant; a lower branch pipe for inlet water; and an upper branch pipe for a steam outlet; wherein the cylindrical body is configured to be arranged horizontally and is curved in a Z-shape with a difference in height, and wherein the bundle of heat exchange tubes is also made in a Z-shape, repeating the bend of the cylindrical body.

2. The reverse steam generator for a lead-cooled fast reactor according to claim 1, wherein the height difference between the curved Z-shaped cylindrical body and the bundle of heat exchange tubes is 0.6-0.7 times the diameter of the cylindrical body, and the bending angle of the cylindrical body and the bundle of heat exchange tubes is 40-45° to horizontal.

Description

[0007] The essence of the claimed invention is illustrated by a drawing, where the FIGURE shows a longitudinal section of the steam generator module.

[0008] The steam generator 1 contains a Z-shaped body 2, inside which there is a Z-shaped tube bundle 13, the edges of the heat exchange tubes 11 of which are fixed in the tube plates 3 of the “hot” lead supply chambers 4 on one side, and in the tube plates 5 of the “cold” lead removal chambers 6 on the other side. Inside the body, the tube bundle rests on intermediate support grids 12. The spherical bottom 15 with the molten lead coolant inlet branch pipe 8, from the reactor core, and the tube sheet 3 form the inlet chamber 4, and the spherical bottom 6 with the “cold” lead coolant outlet branch pipe 9 and the tube sheet 5 form the outlet chamber 16.

[0009] The steam generator is located in a separately fenced-off steam generator box of the NPP containment. The lead coolant melt leaves the reactor core, enters chamber 4 through the branch pipe 8 through the pipeline, then, being distributed over the surface of the tube plate 3, it enters the heat exchange tubes 11 of the tube bundle 13. The cooled lead melt from the pipes 11 flows into the chamber 6 and then returns to the reactor core through the branch pipe 9 through the pipeline. At the same time, the working fluid (feed water at the inlet, overheated steam at the outlet), through the feed water pipeline from the branch pipe 10, enters the body 2 of the steam generator module and the tube bundle 13. In the lower horizontal section of the body 2 and the tube bundle 13, the feed water reaches the saturation temperature, in the vertical section it evaporates, turns into steam, then in the upper horizontal section the generated steam is overheated to the required temperature and, through the upper branch pipe 7 through the hot superheated steam pipeline, it is discharged into the plant turbine.

[0010] The claimed technical solution makes it possible to provide self-compensation for thermal expansion of the structural elements of the steam generator, as well as to reduce their weight. Due to the decrease in height differences in comparison with the vertical design of steam generator modules, the requirements for the main circulation pumps for lead coolant pumping are reduced, as well as operating costs are reduced.