DE3204813A1 - Nuclear power station having a closed coolant-gas circuit for generating process heat - Google Patents

Abstract

A nuclear power station having a closed coolant-gas circuit for generating process heat has a high-temperature reactor and a plurality of heat exchangers for transmitting the thermal energy obtained in a nuclear fashion to a secondary medium. All the components are accommodated in a prestressed concrete pressure vessel, each heat exchanger being located in a shaft accessible from above. From the hot-gas plenum of the reactor there are connected two parallel-flow heat exchangers which form a circuit leg. Two of these circuit legs are in each case assigned a common blower which is installed in a separate shaft in a manner accessible from below. All the heat exchangers and pipes conducting hot gas are under the external overpressure of the cold gas carried back to the reactor core.

Description

Nuclear power plant with closed cooling gas circuit

for generating process heat The invention relates to a nuclear power plant with closed cooling gas circuit for generating process heat, in which the in a high temperature reactor obtained heat from the cooling gas via several heat exchangers is transferred to a secondary medium, the high-temperature reactor in a central Cavern of a cylindrical prestressed concrete pressure vessel is arranged and the heat exchanger as well as these downstream fans in the prestressed concrete pressure vessel vertical shafts are installed so that they can be expanded and in which several radial hot gas ducts, which supply the heat exchangers with hot cooling gas, to one below the reactor core located hot gas collecting chamber are connected.

It is known, nuclear power plants with a closed cooling gas cycle to use to generate process heat and the heat obtained in the reactor core first transferred to an intermediate circuit via a heat exchanger. A heat exchanger suitable for such purposes, which is installed in the pressure vessel of the nuclear reactor is integrated, is described in DE-OS 26 50 922, for example. Used as Peak coolant Helium is used, so is used for the intermediate circuit as well Helium used.

In another nuclear power plant to generate process heat, the Is decoupled from the cooling gas circuit via He / He heat exchangers, there are several Heat utilization circuits connected in parallel are provided, their components - heat exchangers and fans - all housed in the prestressed concrete pressure vessel of the nuclear reactor are. The heat exchanger of this nuclear power plant described in DE-OS 24 11 039 are each divided into a high-temperature part and a low-temperature part, and for both heat exchanger parts there are separate vertical shafts in the prestressed concrete pressure tank intended.

The fan of each heat recovery circuit is immediately below the Arranged low temperature part of the heat exchanger of this circuit.

The state of the art is also a process heating system for generation of synthesis gas, which involves a number of reaction chambers with that in a high temperature reactor The heat obtained is heated. The reaction chambers as well as these downstream Steam generator and blower are in the prestressed concrete pressure vessel of the high temperature reactor integrated. One reaction chamber each, e.g. B. a tube furnace, a steam generator and a fan form a heat utilization circuit. All components can be expanded installed in vertical shafts with the fans directly below the Steam generators are arranged.

Proceeding from this prior art, the object of the invention is based on, in a nuclear power plant of the type described above, the components of the cooling gas circuit and the cooling gas paths to be arranged so that all heat exchangers and pipes carrying hot gas are under external pressure, the components are easily accessible and there is a simple gas flow.

According to the invention, this object is achieved in that in itself As is known, each heat exchanger is inserted into a shaft accessible from above is that two parallel flow heat exchangers are connected to each hot gas duct are that form a circulatory system that every two such circulatory systems one common fan is assigned, which is accessible from below in the lower part Manhole is installed, and that the compressed cold gas on the way from the fans back to the reactor core as a jacket stream around all heat exchangers and hot gas channels is led.

The nuclear power plant according to the invention has the advantage that for four heat exchangers only one fan is available and that distribution devices are not required for the hot gas. The arrangement of the fans on the "cold ends of the heat exchanger as well as the return of the cold compressed Cooling gas along the outside of the heat exchangers and hot gas ducts will take care of this worn so that these components are under external overpressure. This circumstance makes it possible it is necessary to use sliding connections for the components mentioned.

In the case of the hot gas channels, the cold compressed gas is preferred passed through annular channels, each surrounding the hot gas channels and with form them coaxial gas guides.

The ring-shaped channels open into the reactor cavern. In this will the cold gas is first passed through openings in the reactor base plate and flows then along the thermal bottom shield and side shield, these internals be cooled.

The shafts for the two heat exchangers are advantageously located each circulatory line next to one another in an almost radial direction; i.e. the outer Shaft deviates slightly from the radius beam on which the inner shaft is located. At the lower end of the two shafts, a straight coaxial gas duct is provided, whose outer channel connects the two shafts and through their inner channel the external heat exchanger with hot gas from the hot gas duct of this circuit is applied. The heat exchangers are from the bottom up from the hot gas flows through it, which gives off its heat to a secondary medium flowing in the opposite direction.

The duct of each fan can advantageously so between the shafts of the two associated circulatory systems are arranged that all four ducts are equidistant from the fan duct and the cooling gas thus flows through the same paths from the four heat exchangers to the fan and back.

Appropriately, all internal heat exchanger shafts and all external heat exchanger shafts each on a pitch circle around the pressure vessel axis arranged.

In the duct for each fan can be connected to the fan and installed a vertical gas duct extending to the upper end of the duct be, which forms a coaxial line with a surrounding annular channel.

The compressed cold gas is passed through these annular channels led away from the fans.

Each heat exchanger is advantageously through at its upper end a simple straight gas guide with the vertical gas guide of the associated fan tied together. A second straight gas line is provided below this gas line, through which the shaft of each, heat exchanger with the annular channel in the shaft of the fan in question is in communication. Through the first-mentioned gas ducts the cooled gas coming from the heat exchangers is passed on to the fans. The compressed gas enters the heat exchanger shafts through the second gas ducts, in which it flows downward along the outside of the heat exchangers.

The supply lines for the cold secondary medium and the discharge lines for the secondary medium heated in the heat exchangers are expediently according to led out of the prestressed concrete pressure vessel at the top. They are misplaced by the lid with which each heat exchanger shaft is sealed pressure-tight and gas-tight.

The nuclear power plant can in a manner known per se with one of several Existing residual heat removal system must be equipped with fans and coolers. This is advantageously also installed in vertical shafts, the Shafts between the shafts for the heat exchangers on a pitch circle around the Pressure vessel axis are arranged.

In the drawing is an embodiment of the invention Nuclear power plant shown schematically. The figures show in detail: figure 1 shows a longitudinal section through the nuclear power plant along the line 1-1 of FIG. 3, FIG 2 shows a second longitudinal section through the nuclear power plant along the line II-II of the figure 3, Figure 3 the plan view of a section of the nuclear power plant, the two circulatory systems contains.

In a cylindrical prestressed concrete pressure vessel is in a cavern 2 arranged a helium-cooled high-temperature reactor 3, its spherical Fuel elements of existing ern 4 surrounded on all sides by a graphite reflector 5 is.

Ceiling and floor reflectors have openings for the from Helium flowing up and down. A cold gas collection room is located above the ceiling reflector 6 provided. Below the floor reflector, the hot helium is in a hot gas collecting space 7 collected, to which several radial hot gas channels 8 are connected.

The reflector 5 is surrounded by a thermal shield made of metal, which consists of top plate 9, side plate 10 and bottom plate 11. It is between the side plate 10 and the lateral part of the reflector 5, an annular space 12 is formed. Between the thermal bottom shield 11 and a reactor bottom plate arranged inside it 14 ist.ein free space 13 is provided. The reactor bottom plate 14 has a number of breakthroughs for the cooling gas.

The helium cycle is divided into several parallel circulatory rings, each containing a hot gas duct 8 and two He / He heat exchangers 15, which are flowed through in parallel by the hot helium. The heat exchangers 15 can be removed housed in vertical shafts 16 accessible from above. Your feed lines 17 and discharge lines 13 for the secondary helium guided in countercurrent laid through the cover 19 of the shafts 16. Each hot gas channel 8 forms with an annular channel 20 surrounding it, which serves as a cold gas channel, a coaxial gas flow. The cold gas channels enter the reactor cavern 2 directly.

The shafts 16 of each circulatory line lie in an almost radial direction side by side, as can be seen in FIG.

More precisely, their arrangement is made so that each one between Another shaft located in the shafts of two adjacent circulatory systems 21 of all four shafts 16 has the same distance. This only from below accessible shaft is used to accommodate a fan 22, which is located in the lower part of the Shaft 21 is installed. The fans 22 are each two circulatory lines each with two heat exchangers 15 assigned.

The internal shafts 16a of the heat exchanger 15 as well as the outer shafts 16b of these components are each on the same pitch circle arranged around the pressure vessel axis. On another pitch circle around the pressure vessel axis four vertical shafts 23 are also provided (only one is shown in FIG. 3), each of which houses a fan and a cooler. These form together the residual heat removal system of the nuclear power plant (not shown) the both shafts 16a and 16b of each circulatory line are through at their lower end a straight coaxial gas line connected, the outer channel 24 directly into the both shafts opens, while its inner channel 25 to the two heat exchangers 15 is connected. The heat exchanger 13 located in each case in the shaft 16a is also connected directly to the hot gas duct 8 of this circuit. The heat exchanger 15 in the shaft 16b is supplied with hot gas through the inner channel 25 applied. The hot gas flows through both heat exchangers from bottom to top.

The upper part of each duct 21 for one of the fans 22 is in Narrowed diameter. In this part, a vertical gas duct 26 is laid, which is connected to the respective fan 22. It forms with one surrounding it annular channel 27 a coaxial line. The channel 27 is used to return the compressed cold gas. It is connected to four simple straight gas ducts 29, the top of each of the four heat exchangers associated with the fan 22 in the shaft 16 15 enter. Four more simple gas guides 28 that are above the gas guides 29 are arranged, connect the upper ends of these four heat exchangers with the vertical gas guide 26 and thus direct the cooled in the heat exchangers 15 Helium to the fan 22.

In all shafts 16 is in the area between the E-in opening points of the two gas ducts 28 and 29 installed a seal 30, which prevents the outflow prevents compressed gas in the upper part of the shaft.

The following is the guidance of the cooling gas flow shown by arrows described by the nuclear power plant according to the invention in context.

The helium entering the reactor core 4 from above is heated during the When the fuel element flows through, it is collected in the hot gas collecting space 7 and is then distributed through the hot gas ducts 3 to the individual parallel-connected Circulatory cords. There is then another division in each circuit on the two heat exchangers 15 of this strand instead, with the helium to the outside Heat exchanger passes through the inner channel 25. In the heat exchangers 15 flows the hot helium upwards, gives its heat energy to the secondary helium from and then occurs through the gas guides 28 in the vertical gas guide 26 of the associated fan 22 a.

After it has been compressed in the fans 22, the cold helium flows outside along the gas guide 26 through the annular channel 27, divides in each case on the four connected gas guides 29 and is fed back into the shafts 16. In the shafts 16, the compressed helium flows on the outside of the heat exchangers 15 along down. The heat exchangers are therefore under external overpressure. Therefore can - as can be seen from Figure 1 - sliding connections in the heat exchangers can be used. The same also applies to the hot gas channels 8 and the inner ones Channels 25.

From the heat exchanger shafts 16a, the cold gas passes directly into the Cold gas channels 20; the gas emerging from the shafts 16b is only through the outer channels 24 before it also enters the cold gas channels 20.

In the reactor cavern 2, the partial flows of all circulation lines unite again, and the Kaltgås is first through the breakthroughs in the reactor bottom plate 14 into room 13. -Here it flows along the thermal bottom shield 11, which it cools in the process. In the annular space 12 between the side reflector and thermal Side plate 10 we lead the cold gas upwards, with the side plate also the cold gas is cooled, and enters the Kaltgassammeiraum 6.

The passes through the openings in the ceiling reflector Finally, the helium is returned to the fuel assembly. Blank page

Claims (9)

Claims (1! Kernkraftverk with closed Nühlgaskkreislauf for the generation of process heat, in which the obtained in a high temperature reactor Transferring heat from the cooling gas to a secondary medium via several heat exchangers is, the high-temperature reactor in a central cavern of a cylindrical prestressed concrete pressure vessel is arranged and the heat exchanger and these downstream fans in the The vertical shafts located in the prestressed concrete pressure vessel can be removed are and in which several radial hot gas channels, which the heat exchanger with hot Supply cooling gas to a hot gas plenum located below the reactor core are connected, characterized in that each in a known manner Heat exchanger (15) is inserted into a shaft (16) accessible from above, that two parallel flow heat exchangers (15) are connected to each hot gas duct (8) are that form a circulatory system that every two such circulatory systems one common fan (22) is assigned, which is accessible from below in the lower part of a Shaft (21) is installed, and that the vertical cold gas on the way from the Blowers (22) back to the reactor core (4) as a jacket flow around all heat exchangers (15) and hot gas channels (8) is guided. 2. Nuclear power plant according to claim 1, characterized in that each The hot gas channel (8) is coaxial with an annular channel (20) surrounding it Forms gas guide, in which the compressed cold gas through the annular channel (20) is passed, and that the annular channel (20) into the reactor cavity (2) flows out. 3. Nuclear power plant according to claim 1, characterized in that the Shafts (16) for the two heat exchangers (15) of each circuit in almost radial direction lie next to each other and that at their lower end a straight coaxial gas guide is provided, the outer channel (24) of which the two shafts (16a, 16b) and through their inner channel (25) the external heat exchanger (15! is acted upon by hot gas from the hot gas duct (8) of this circuit. 4. Nuclear power plant according to claim 3, characterized in that the Shaft (21) of each fan (22) in this way between the shafts (16a, 16b) of the two associated circulatory system is arranged that all four shafts (16a, 16b) the have the same distance from the fan shaft (21). 5. Nuclear power plant according to claim 3 or 4, characterized in that all internal heat exchanger shafts (16a) and all external heat exchanger shafts (16b) are each arranged on a pitch circle around the pressure vessel axis. 6. Nuclear power plant according to claim 1, characterized in that in the Shaft (21) for each fan (22) one connected to the fan (22) and installed up to the upper shaft end extending vertical gas guide (26) which forms a coaxial line with an annular channel (27) surrounding it, and that the cold gas compressed in the fan (22) through the annular channel (27) to be led. 7. Nuclear power plant according to claim 6, characterized in that the upper end of each heat exchanger (15) through a straight gas guide (28) with the vertical Gas guide (26) of the associated fan (22) is connected and that another, below the first straight gas duct (29) arranged the shaft (16) of each heat exchanger S (15) with the annular channel (27) in the shaft (21) of the associated fan (22) connects. 8. Nuclear power plant according to claim 1, characterized in that the Supply and discharge lines (17, 18) for the secondary medium of the heat exchanger (15) are led out of the prestressed concrete pressure vessel (1) upwards. 9. Nuclear power plant according to claim 1, characterized in that in further vertical shafts (23) located in the prestressed concrete pressure vessel (1) several looms and coolers existing residual heat removal system is installed and that the shafts (23) between the shafts (16) for the heat exchangers (15) are arranged on a pitch circle around the pressure vessel axis.