DE3822212C1 - Nuclear reactor installation consisting of a high-temperature small reactor, a helium/helium heat exchanger and a helium/water heat exchanger - Google Patents

Abstract

The invention relates to a nuclear reactor installation arranged in a steel pressure vessel and having a helium-cooled high-temperature small reactor, a helium/helium heat exchanger and at least one helium/water heat exchanger for the generation of steam. It is the object of the invention to develop such an installation in such a way that both heat exchangers can be subdivided on their secondary side in a simple way into a plurality of systems. According to the invention, both heat exchangers are enclosed by a gas guide jacket and are arranged one under the other around the core (inner) tube. The supply and removal of the secondary medium for the lower heat exchanger - preferably the helium/helium heat exchanger - takes place via a horizontal stub which comprises two coaxially arranged tubes, the inner tube conveying the hot medium having a perforated-plate collector and the outer tube conveying the cold medium being designed as a drum-type collector. The connection conduits to the heat exchanger are sited, in the case of the perforated-plate collector, through the core tube and, in the drum-type collector, in the annular space between the pressure-container wall and the gas guide jacket. The upper heat exchanger is connected to perforated-plate collectors which are installed in the gas guide jacket by means of sliding connections.

Description

The invention relates to a nuclear reactor plant with the in the upper Concept of claim 1 specified features.

A nuclear reactor plant according to the preamble of claim 1 belongs to the prior art because of the unpublished DE-PS 38 19 485. Another nuclear reactor plant is known from DE-OS 34 46 101. In this plant, a first He / He heat exchanger bundle extends above the small HT reactor through the entire reactor pressure vessel, the diameter of which is enlarged in its upper part. In this extended area, a further He / He heat exchanger bundle is arranged coaxially to the first one, below which the He / H ₂ O heat exchanger intended for removing the after heat is installed. This can also be divided into two systems with separate H ₂ O supply and discharge lines. For the supply of the secondary helium to the second He / He heat exchanger bundle several ports are attached to the side of the reactor pressure vessel, which are connected to a ring collector. A further ring collector is provided above the first He / He heat exchanger bundle, which is connected by lines to the tubes of this bundle.

In DE-OS 32 12 264 a nuclear reactor system is also be written, which has a small HT reactor as an energy source and egg NEN He / He heat exchanger as a heat utilization system, both of which are housed in a steel reactor pressure vessel. The He / He heat exchanger, which is arranged around a central tube and has an annular cross section, is surrounded by three HE / H ₂ O heat exchangers, which are provided for the after-heat operation. The secondary helium is fed to the He / He heat exchanger through a ring collector.

DE-OS 34 35 255 is also mentioned as prior art, in which the heat exchanger serving the heat removal between between the small HT reactor and the main heat exchangers (at for example, steam generators) are arranged. That in the HT Small reactor heated cooling gas is initially controlled by a central Hot gas pipe led up to where it redirected and then from is fed to the main heat exchangers above.

Starting from the first-mentioned publication, the Invention, the object of a nuclear reactor plant with the Features of the preamble of claim 1 to train that a division of the two heat exchangers on their Se is possible in a simple way.

This problem is solved by the characteristic features of claim 1.

In the nuclear reactor plant according to the invention, in the primary egg only one gas supply is required, can be on the second därseite the heat exchanger through the special arrangement of the Collectors easily subdivide into several units be taken what the availability of the entire facility he increases. Another advantage is that a subsequent installation the heat exchanger in existing systems (namely by Aus exchange) is possible because the heat exchanger is a compact assembly form a unit. You also need relatively little space.

Advantageous developments of the invention are the Unteran say and the following description of an embodiment game in connection with the schematic drawing ent  to take.

The figure shows the upper part of a nuclear reactor plant according to the invention in longitudinal section.

The figure shows a reactor pressure vessel 1 made of steel, which is retracted in its central part 1 a and in its upper part has an enlarged diameter area 2 . In the lower part, a small HT reactor (not shown) is installed, the core of which is flowed through from bottom to top by primary helium and can be formed by a bed of spherical fuel elements. Above the HT-Kleinre actuator is a hot gas plenum. 3 A core tube 4 runs centrally through the two container parts 1 a and 2 .

In part 1 a of the reactor pressure vessel 1 , a He / He heat exchanger 5 and a He / H ₂ O heat exchanger 6 are installed as heat usage systems, which have an annular cross section and are arranged around the core tube 4 . In the example shown, the He / He heat exchanger 5 is at the bottom. Depending on the task for the heat exchanger and the thermodynamic boundary conditions, the He / He heat exchanger can also be arranged above the He / H ₂ O heat exchanger.

Both heat exchangers 5 and 6 are completely enclosed by a gas guide jacket 7 for the primary helium. To the sheet metal jacket 7 , two parallel-connected order blowers 9 are connected via lines 10 , each of which is accommodated in a pressure vessel 1 placed on the reactor housing 8 .

The tube plates 11 for the bundle tubes of the He / H ₂ O heat exchanger 6 arranged at the top are fastened to the core tube 4 and to the gas guide jacket 7 ; the tube plates 12 for the bundle tubes of the He / He heat exchanger 5 arranged below, however, are only attached to the gas guide jacket 7 .

The primary hot helium flows from the hot gas collecting space 3 from below into the He / He heat exchanger 5 and is guided outside along the bundle tubes upwards, wherein it gives off its heat to the secondary helium flowing through the bundle tubes. Then the primary helium enters the He / H ₂ O heat exchanger 6 and leaves it through the blowers 9 leading to the two circulating lines 10 . After it has been compressed in the circulating fans 9 , the primary helium is conducted downwards along the outside of the sheet metal jacket 7 and passes through an annular space in the pressure vessel part containing the small HT reactor to a cold gas collecting space (not shown).

In the enlarged area 2 of the reactor pressure vessel 1 , a nozzle 13 is placed horizontally, which has two tubes, the inner tube 14 and the outer tube 15 , which form a coaxial gas duct. The two tubes 14 and 15 are connected to the core tube 4 , the upper end 16 in the direction of the Stut zen 13 is angled by 90 °. The outer tube 15 is connected to the core tube 4 by a sliding connection 17 .

The connection point of the inner tube 14 is designed as a perforated plate collector 18 . The inner tube 14 is provided with thermal insulation 19 on its circumference. The part of the outer tube 15 located between the core tube 4 and the pressure vessel wall is designed as a multi-row drum collector 20 .

At the drum collector 20 connecting lines 21 follow, which run through an annular space 22 between the pressure vessel wall and the gas guide jacket 7 to the upper end of the He / He heat exchanger 5 and end in the tube plates 12 . At the lower end of the He / He heat exchanger 5 there are further connecting lines 23 which are led upwards through the core tube 4 and are connected to the perforated plate collector 18 . The core tube 4 has in the part which is located within the He / He heat exchanger 5 , an expanded area 24 in which the connecting lines 23 have an expansion zone 25 .

Through the outer tube 15 of the coaxial gas conduction, cold tertiary helium is introduced into the reactor pressure vessel 1 , which is distributed to the connecting lines 21 by means of the drum collector 20 . The hot secondary helium discharged from the He / He heat exchanger 5 is - after it has flowed through connection lines 23 and has reached the perforated plate collector 18 - passed through the inner tube 14 to the outside. This has the part before that the temperature gradient to the nozzle 13 is only slight. By laying the cold secondary helium transpor ting connecting line 21 in the annular space 22 , thermal insulation of the core tube 4 can also be omitted.

For the supply of the He / H ₂ O heat exchanger 6 with feed water or the discharge of the generated steam from the reactor pressure vessel 1 , a feed line (not shown) or discharge line 26 is provided, which extends horizontally through the expanded area 2 of the pressure vessel 1 performed and attached to the pressure vessel wall by means of a heat expansion sleeve 27 . In the drawing, only the derivative 26 lies in the sectional plane; the supply line offset by 90 ° has the same design features as this. Supply and discharge 26 each end in a perforated plate collector 28 , which is inserted by means of a sliding connection 29 in the gas guide jacket 7 . The perforated plate collector 28 of the derivative 26 is connected by lines 30 to the bundle tubes Chen located at the lower end of the He / H ₂ O heat exchanger 6 .

The perforated plate collector 28 of the He / H ₂ O heat exchanger 6 and the perforated plate collector 18 and the drum collector 20 of the He / He heat exchanger 5 can be reached from the outside, so that a blind from individual tubes by means of a remote-controlled manipulator is possible.

Claims (6)

1. Nuclear reactor plant consisting of

• a) a gas-cooled HT small reactor, the core of which is flowed through from bottom to top by primary helium,
• b) at least one He / He heat exchanger ( 5 ) with a cross-section, in which the primary helium emits its heat to secondary helium circulating in an intermediate circuit,
• c) at least one He / H ₂ O heat exchanger ( 6 ) for generating steam,
• d) a reactor pressure vessel ( 1 ) made of steel, in which
  • d1) the HT small reactor and above that which are installed in the heat exchanger ( 5, 6 ) and
  • d2) which has at its upper end a region ( 2 ) widened in diameter,
• e) a core tube ( 4 ) arranged in the reactor vessel ( 1 ), around which the two heat exchangers ( 5, 6 ) are arranged one below the other,
• f) one of the cold and the hot helium from each other, the gas routing Blechman tel ( 7 ), which closes the two heat exchangers ( 5, 6 ),
• g) one led horizontally into the reactor vessel ( 1 ) and in each case in a perforated plate collector ( 28 ) ended supply and discharge line ( 26 ) for the upper heat exchanger ( 6 ), the perforated plate collector ( 28 ) by means of a sliding connection ( 29 ) in the Blechman tel ( 7 ) is used,
• h) blow at least two circulators lying in the cold gas stream ( 9 ),

characterized by the following features:

• i) the supply and discharge of the secondary medium for the lower heat exchanger ( 5 ) via a to the extended area ( 2 ) of the reactor pressure vessel ( 1 ) horizontally attached nozzle ( 13 ), the two coaxial, connected to the core tube ( 4 ) Pipes ( 14, 15 ) comprises, wherein
  • i1) the junction of the hot medium leading in nenrohres ( 14 ) as perforated plate collector ( 18 ) is ausgebil det and
  • i2) the cold medium leading outer tube ( 15 ) in the area between the pressure vessel wall and the core tube ( 4 ) is designed as a drum collector ( 20 );
• k) the hot tube bundle end of the lower heat exchanger ( 5 ) is connected to the perforated plate collector ( 18 ) by connecting pipes ( 23 ) laid in the core tube ( 4 );
• l) the cold tube end of the lower heat exchanger ( 5 ) is connected to the drum collector ( 20 ) by connec tion lines ( 21 ) which run in the annular space ( 22 ) between the pressure vessel wall and the Blechman tel ( 7 ).

2. Nuclear reactor plant according to claim 1, characterized in that

• m) that within the core tube ( 4 ) at least one expansion zone ( 25 ) for the Ver in the core tube ( 4 ) Ver connecting lines ( 23 ) is available.

3. Nuclear reactor plant according to claim 2, characterized in that

• n) that the part of the core tube ( 4 ) located in the lower heat exchanger ( 5 ) is expanded in its diameter and in this area ( 24 ) the expansion zone ( 25 ) is provided.

4. Nuclear reactor plant according to one of claims 1 to 3, characterized in that

• o) that the upper end of the core tube ( 4 ) is angled in the direction of the socket ( 13 ) by 90 ° and is connected via a sliding connection ( 17 ) with the cold medium leading outer tube ( 15 ).

5. Nuclear reactor plant according to one of claims 1 to 4, characterized in that

• p) that the tube plates ( 11 ) for the bundle tubes of the obe ren heat exchanger ( 6 ) on the core tube ( 4 ) and on the sheet metal jacket ( 7 ) are attached.