DE2435358B2 - NUCLEAR ENERGY PLANT WITH CLOSED WORKING GAS CIRCUIT - Google Patents

Description

The invention relates to a nuclear power plant with a closed working gas circuit in which inside an outer containment vessel, a reactor core that heats the working gas, a turbine set with a generator driven by the working gas, and others Components of the working gas circuit, such as heat exchangers and gas stores, are arranged, with The reactor core is separated from the turbo set and the other components in a separate reactor room with walls made of prestressed concrete and with individual chambers for the components are provided.

In the case of nuclear energy systems, it is necessary to control the machines and devices through which the working gas flows of the system, such as the turbo set and other components of the working gas circuit, in radiation-protected To arrange rooms in order to prevent the operating personnel from being endangered by radioactive radiation. It is necessary to take safety precautions also in the event of a possible breakage the working gas lines are the chambers in which the components of the working gas circuit are housed withstand the excess gas pressure that then arises within the chambers and reactor shutdown device and the residual heat removal system are not endangered. For the construction of tanks for nuclear power plants with high pressure Working gas is therefore - in contrast to nuclear energy plants with light water reactors (cf. »Kerntechnik«, 1968. pp. 462 to 464) - as building material Prestressed concrete used. In addition, the aim is to keep the machines and devices easily accessible from the outside To accommodate chambers so that the machines and apparatus can be expanded without difficulty and necessary repairs to the components of the nuclear power plant are not immediately in the Radiation area of neighboring machines and devices must be carried out.

It is already known. Turbo set and heat exchanger in a separate room below the reactor room to accommodate, both the reactor room and the engine room walls made of prestressed concrete have (DT-AS 16 14 610). In this nuclear power plant, the working gas is supplied via gas pipes, which penetrate the partition walls between the reactor room and the engine room, from the reactor room to the Turboset and led back from the heat exchangers into an annular space surrounding the reactor core. Such a system can only be implemented with great technical effort. Another disadvantage is that the components of the nuclear power plant are difficult to access.

Furthermore, from DT-OS 17 64 249 known several Turbo sets and the associated heat exchangers separated from the reactor space in individual chambers to accommodate, the chambers within the prestressed concrete container surrounding the reactor core radially are arranged distributed around the axis of the reactor core. To reduce the required with this arrangement The volume of the prestressed concrete container is based on one of the DT-OS 22 41 426 and from »nuclear technology«, 1974, p. 323 to 325 known proposal provided with axially parallel arrangement of the heat exchanger the turbo set below the space for the reactor core in a separate chamber with openings, which are secured with locks, can be used in a horizontal position and can be removed. Even if this is the Dimensions of the prestressed concrete container could be reduced, so this type of construction remains there is a relatively large space enclosed by prestressed concrete, which reduces the costs of construction the system is significantly affected. In addition, it is disadvantageous in nuclear power plants of this type that although the turbo set is arranged inside the prestressed concrete tank, but the one connected to the turbo set Generator is arranged outside of the prestressed concrete tank, so that a shaft bushing through the Wall of the prestressed concrete tank through is necessary. One of all safety regulations for nuclear power plants Sufficient shaft penetration can only be achieved with great technical effort. aside from that it is disadvantageous that the generator arranged outside the prestressed concrete container has a separate support needed.

The object of the invention is to provide a nuclear power plant that operates with a closed working gas circuit

create, in addition to good accessibility the components of the nuclear power plant in the event of a break in the gas pipes safety in increased Dimensions is guaranteed and in which a cost reduction in the manufacture of the system can still be achieved is

This object is achieved in a nuclear power plant of the type specified in that the reactor core is located in a separate prestressed concrete container, which is inserted into a corresponding recess one of the combs. ' exhibiting, with its outer ' Wall used on the vertical inner wall of the outer containment container adjoining the concrete container is, and that in one of the chambers of the concrete container the turbine set is housed together with the generator

The advantage of this nuclear power plant is that everything is connected to the reactor core via gas ducts standing components of the system housed in chambers of a separate concrete container and are therefore spatially easily accessible. The chamber walls serve as splinter protection in the Case of bursting machine parts or cooking guide lines as well as shielding against radioactive ones Radiation. The concrete container is simple in construction and using inexpensive building materials manufacturable. At the same time, the chambers used to hold the components form a closed one and earthquake-proof unit. It is also advantageous that the generator driven by the turbine generator is housed within the concrete container.

In another embodiment of the nuclear energy plant according to the invention it is provided that the chambers of the concrete container for the installation and removal of the components of certain openings with gas-tight, and PE ys gen the escape of radioactive substances fastenings having This ensures that defective components for Repair work can easily be removed.

To increase the safety of the nuclear power plant, a further embodiment of the nuclear power plant according to the invention consists in that the chambers of the concrete container are equipped with safety locks which prevent excess gas pressure. With the accommodation of each individual component of the nuclear power plant in a special chamber, the components accommodated in adjacent chambers and in particular the units of the plant required for safety are protected from damage in the event of a break in one of the apparatus in the working gas circuit or a line. The partition walls between the chambers of the concrete container expediently have overflow openings so that sufficient space is available to accommodate the hot working gases escaping in the event of fractures and the chamber walls are not inadmissibly stressed. Overheating of the partition walls is preferably prevented in that all or some of the chambers of the concrete container are equipped with heat-insulating insulation. *> ⁰

The invention is explained in more detail using an exemplary embodiment shown in the drawing. It shows

F i g. 1 shows a nuclear power plant according to the invention in a longitudinal section,

F i g. 2 the same nuclear power plant in a longitudinal section along the section line II-II according to FIG. 1,

Fig. 3 the same nuclear power plant in cross section according to the section line IH-III according to F i g. 1.

As can be seen from the drawing, the nuclear power plant consists of an outer, prestressed concrete manufactured security container 1 and from one with its outer wall 2 to the vertical inside the security container 1 adjacent concrete container 3, which has a recess 4 for a to accommodate the Reactor core 5 has certain inner prestressed concrete container 6. Inside the concrete container 3 are individual Chambers 7 to 12 for receiving the horizontally arranged turbine set 13 with generator 14 as well for the other components of the working gas cycle, such as a recuperative heat exchanger 15, pre-cooler 16, intercooler 17, gas storage 18 and an after-heat removal system 19 are provided. Each individual chamber is expediently adapted to the component to be accommodated in it and designed in accordance with the specified safety requirements, so that from an economic point of view optimal room design is possible. The wall thicknesses and the structure of the walls correspond the forces to be transferred or become effective on the walls and the necessary radiological Shielding function as well as the function of the walls as splinter protection in the event of a possible bursting one of the components housed in the chambers.

Above the concrete container 3, the nuclear power plant has an assembly room that can be accessed from the outside 20 on. The assembly space 20 is expediently laterally by one of the outer wall 2 of the concrete container 3 limited upwardly extended wall 21, which, like the outer wall 2 of the concrete container 3 adjoins the inside of the outer security container 1. The wall 21 serves on the one hand as a support structure for the track of a chamber that is movable above the chambers intended for receiving the components Crane 22 on the other hand as an assembly aid in the erection of the outer containment 1, the is provided with a liner on the inside. This training is also an improvement the earthquake safety of the nuclear power plant achieved.

The chambers have openings for the installation and removal of the components arranged in the chambers 7 to 12 with gas-tight closures 23 secured against the escape of radioactive rays. At the for the heat exchangers are determined, extending in the vertical direction chambers 8 to 12 Closures 23 are attached in the boundary wall of the concrete container 3 to the assembly space 20. To Loosen the closures 23 and after loosening the pipe connections to the respective heat exchanger to be dismantled can the heat exchanger - as in FIG. 1 schematically for the recuperative heat exchanger 15 is shown - lift into the assembly space 20 and transport it out of the nuclear power plant from here. The chambers 7 to 12, in which the Machines and apparatus carrying working gas are housed because of the radioactive radiation of the machines and apparatus as a result of the working gas passed through the apparatus, or only to a limited extent Duration of stay accessible. It is therefore advisable to put the in the concrete container Chambers 7 to 12 adjacent - interconnected, accessible rooms 24 provided.

The rooms 24 are ventilated and are accessible via entrances 25 or through the use of locks

26, which are used in the walls of the security container 1, accessible. The accessible rooms 24 are available with chambers 27 to 29 for the ventilation system 30 with active gas cleaning, the control system 31 and for others Measuring devices 32 in connection. Between the accessible rooms 24 and the chambers 7 to 12 and 27 to 29, safety closures 33 are provided, which are in the event of an impermissibly high gas overpressure open in one of the chambers so that the hot working gases escaping in the event of fractures without the chamber walls to overuse can be deducted. There is an overflow within the chambers 7 to 12 of the exiting working gases in adjacent chambers via overflow openings 34 through which also gas ducts are laid or those to accommodate the pipe connections and shut-off devices serve, possible.

Conveniently, in the concrete container 3 above the chamber 7, in which the turbo set 13 with generator 14 are installed, one protected by a splinter protection cover 35 that closes off the chamber 7 at the top Fittings space 36 is arranged. The one from the reactor

5 hot gas lines 3 ′ leading to the turbo set 13 are passed through the spit protection cover 35.

The prestressed concrete container 6, which receives the reactor core ί, forms one of the other buildings de Nuclear energy plant to be built separately for the maintenance or inspection of the prestressed concrete ίο holder 6, such. B. the re-tensioning of Spannkabeli or the control of the measuring instruments checking the reactions is a between pre-stressed concrete containers

6 and concrete container 3 free space inside the recess 4 is provided.

In the embodiment are dei on the walls Chamber 7 and in the fittings room 36 heat insulating de isolations 38 attached. Prevent these isolations in the event of a break in one of the hot gas lines, overheating of the walls of the concrete container 3.

For this purpose 3 sheets of drawings

Claims (5)

Patent claims: 1. Nuclear energy plant with closed working gas circuit, in the case of a working gas that heats the working gas inside an outer containment Reactor core, a working gas driven turbine set with generator and other components of the working gas circuit, such as heat exchanger and gas storage, are arranged, the reactor core separated from the turbo set and the other components in a separate reactor room with walls made of prestressed concrete «and with individual chambers for the components are provided, characterized in that that the reactor core (5) is in a separate prestressed concrete container (6), which is in a corresponding recess (4) of one of the chambers (7 to 12, 27 to 29) having, with its outer one Wall (2) adjoining the vertical inner wall of the outer containment container (1) Concrete container (3) is inserted, and that in one (7) of the chambers (7 to 12) of the concrete container (3) the turbo set (13) is housed together with the generator (14) 2. Nuclear energy plant according to claim 1, characterized in that the chambers (7 to 12) of the concrete container (3) for the installation and removal of the components (13 to 19) certain openings with gas-tight and secured against the escape of radioactive substances \ tapped (23). 3. Nuclear power plant according to claim 1 or 2, characterized in that the chambers (7 to 12, 27 to 29) of the concrete container (3) with safety locks (33) to prevent excess gas pressure are equipped. 4. Nuclear power plant according to one of claims 1, 2 or 3, characterized in that the Have partition walls between the chambers (7 to 12) of the concrete container (3) upstream openings (34). 5. Nuclear energy plant according to one of the preceding claims, characterized in that the chambers (7 to 12) of the concrete container (3) all or in part with a heat-insulating insulation (38) are equipped.