EP4128282A1

EP4128282A1 - Device for controlling a plurality of nuclear reactors

Info

Publication number: EP4128282A1
Application number: EP21732368.2A
Authority: EP
Inventors: Laurent AMICE; Thierry Lucidarme; Christopher John Wright; Jan Jasper VAN DEN BERG
Original assignee: Electricite de France SA
Current assignee: Electricite de France SA
Priority date: 2020-03-24
Filing date: 2021-03-24
Publication date: 2023-02-08
Also published as: WO2021191564A1; CN115668403A; FR3108769B1; FR3108769A1

Abstract

The invention relates to a device for controlling a plurality of nuclear reactors, comprising, for each nuclear reactor, a plurality of sensors for measuring operating parameters as well a system for controlling the nuclear reactor.

Description

DESCRIPTION

TITLE: Control system for a plurality of nuclear reactors GENERAL TECHNICAL FIELD

The present invention relates to the field of nuclear reactor control systems, and more particularly to the predictive maintenance of nuclear reactors.

STATE OF THE ART

The maintenance and monitoring of nuclear reactors are technically demanding areas due to the complexity of the reactors themselves. This complexity tends to increase the risk of human error during maintenance and monitoring operations, in particular during certain particularly repetitive and frequent steps. In addition, their complexity requires the use of highly qualified and experienced personnel in a large number of different technical fields.

Current solutions consist of dedicating teams to operating and monitoring a reactor, and bringing together the operating and monitoring equipment of a reactor in a single control room entirely dedicated to this single reactor. While these solutions may appear satisfactory in the case of the monitoring of high power reactors located in an energy production plant, they imply the continuous presence on site of an operating team for each nuclear reactor, which may be necessary. prove to be particularly expensive when the reactors are numerous and / or dispersed, as in the case of small modular reactors (in English Small modular reactors, abbreviated as SMR).

PRESENTATION OF THE INVENTION

In order to reduce the operating costs of nuclear reactors while maintaining the necessary level of safety, it is therefore proposed according to a first aspect, a device for controlling a plurality of nuclear reactors, comprising for each nuclear reactor a plurality of sensors intended to measure operating parameters and a system for controlling the nuclear reactor, characterized in that it further comprises:

- A system for monitoring the state of each nuclear reactor, in communication with all the sensors of the plurality of nuclear reactors, and comprising a database of the state of nuclear reactors, the database of the state of nuclear reactors comprising, for at least one nuclear reactor and for at least a given instant, data relating to:

. at the level of use of the nuclear reactor,

. the use of nuclear reactor components,

. the operating parameters of the nuclear reactor,

. the state of the nuclear reactor fuel,

. planned changes in the utilization rate of the nuclear reactor; and

- A maintenance operations planning system, in communication with the state monitoring system of each nuclear reactor, comprising a maintenance operations database, in which are recorded data relating to maintenance operations, as well as '' a human-machine interface (HMI) allowing a nuclear reactor supervisor to add data relating to maintenance operations to the database of maintenance operations, the data relating to maintenance operations comprising:

. a maintenance operation to be carried out,

. a nuclear reactor on which the maintenance operation must be carried out,

. a time and a date at which this operation must be carried out.

The invention is advantageously completed by the following characteristics, taken alone or in any of their technically possible combination: - The control system of a plurality of nuclear reactors comprises a single central monitoring system of the state of all the nuclear reactors.

- The control system for a plurality of nuclear reactors comprises a single central planning system for the maintenance operations of all the nuclear reactors.

- The control device of a plurality of nuclear reactors comprises a dedicated monitoring system for each nuclear reactor according to a distributed architecture.

- All the monitoring systems of each nuclear reactor communicate via a data exchange network in order to update the database of the state of the nuclear reactors of each monitoring system according to the evolution of the state of the other nuclear reactors of the plurality of nuclear reactors.

- The control device of a plurality of nuclear reactors comprises a dedicated maintenance operations planning system for each nuclear reactor according to a distributed architecture.

- All of the maintenance operations planning systems for each nuclear reactor communicate via a data exchange network in order to update the database of maintenance operations for each monitoring system according to the planned maintenance operations for the other nuclear reactors of the plurality of nuclear reactors.

- Each nuclear reactor communicates with the others via a data exchange network via an independent communication link which has been the subject of a security association prior to data exchange, guaranteeing confidentiality, authentication and integrity of communication

- The nuclear reactors of the plurality of nuclear reactors are small modular reactors.

- The maintenance operations to be carried out are either inspection operations of a component of a nuclear reactor by personnel operation of one of the nuclear reactors, that is, tests carried out automatically by the control system of a nuclear reactor.

- A level of importance for the proper functioning of each nuclear reactor is assigned to maintenance operations.

- Two levels of importance are possible, these two levels being critical and non-critical.

- Critical maintenance operations may concern systems, structures or components related to safety, the environment, security or availability:

- The reactor in operation;

- reactor safety or safeguard systems;

- the reactor protection system;

- classified auxiliary systems:

. ventilation,

. control command,

. electrical distribution,

. emergency diesel,

. refrigeration systems,

. the pumping station, and. containment;

- the turbo-alternator unit and its auxiliaries for operation:

. the condenser,

. the water station,

. the cooling circuit,

. the transformer, and. the evacuation station

- Non-critical maintenance operations include maintenance operations related to other systems, structures or components:

- adjustment of load or frequency setpoints (remote setting);

- treatment of effluents and waste;

- the demineralization station;

- the production of auxiliary steam; - site works;

- general services.

- For critical operations, the monitoring device leaves control of each nuclear reactor to the control system or to the respective operating personnel of each of said nuclear reactors, and is content to collect the measured data, while for non-critical operations , the monitoring device can deliver instructions or commands to the respective control systems of the nuclear reactors.

- For critical or non-critical operations, the planning system transmits to the reactors concerned a schedule of maintenance operations corresponding to a standard schedule of maintenance operations defined for a selected standard nuclear reactor, or a schedule personalized to each reactor according to its condition and data recorded in the nuclear reactor condition database.

- When a maintenance operation to be carried out is a test carried out automatically by the control system of a nuclear reactor, the command making it possible to start the test process is sent directly by the control device.

- When a maintenance or inspection operation of an element of a nuclear reactor is to be carried out or to be triggered by the operating personnel, the control device issues a notification to the address of the operating personnel indicating the maintenance or inspection operation of the nuclear reactor component to be carried out, the nuclear reactor concerned, as well as the time remaining before the time and date before which the maintenance or inspection operation of the element of the nuclear reactor must be achieved.

- Following the performance of a maintenance operation, a report on the progress of the maintenance operation is added to the data relating to the maintenance operation.

- The report on the progress of the maintenance operation includes, in the case of a test carried out automatically, a record of the procedure and information about the test results.

- The report on the progress of the maintenance operation includes, in the case of an inspection of an element of the nuclear reactor, information relating to the state of the element of the nuclear reactor inspected.

- Where applicable, data relating to additional maintenance operations are added automatically following the addition of a report on the progress of a maintenance operation to the data relating to maintenance operations.

- The maintenance operations planning system learns, during its operation, which additional maintenance operations are to be added automatically according to the contents of the report on the progress of a maintenance operation. Learning may include:

. analysis of the content of all reports on the progress of a maintenance operation recorded by the maintenance operations planning system in the maintenance operations database in order to determine new maintenance operations or modifications the frequency at which certain maintenance operations must be carried out, or

. training an artificial learning model from the data recorded by the maintenance operations planning system in the maintenance operations database in order to determine an optimal maintenance strategy.

According to a second aspect, the invention proposes a method for monitoring a plurality of nuclear reactors, comprising, for each nuclear reactor, steps for measuring operating parameters using a plurality of sensors and for monitoring said nuclear reactor. , characterized in that it further comprises the steps of:

- monitoring the state of each nuclear reactor, on the basis of the information provided by all the sensors of the plurality of nuclear reactors, and on the basis of information contained in a database of the state nuclear reactors, the database of the status of nuclear reactors comprising, for at least one nuclear reactor and for at least a given time, data relating to:

. at the level of use of the nuclear reactor,

. the use of nuclear reactor components,

. the operating parameters of the nuclear reactor,

. the state of the nuclear reactor fuel,

. planned changes in the nuclear reactor utilization rate; and - planning maintenance operations, on the basis of the information collected at the stage of monitoring the state of each nuclear reactor and on the basis of information contained in a database of maintenance operations, in which are recorded data relating to maintenance operations, taking into account data from maintenance operations added by a man-machine interface (HMI) allowing a nuclear reactor supervisor to add data relating to maintenance operations, data relating to maintenance operations including:

. a maintenance operation to be carried out,

. a nuclear reactor on which the maintenance operation must be carried out,

. a time and a date at which this operation must be carried out.

Said method may further comprise the steps which consist in finding a level of importance for the proper functioning of each nuclear reactor attributed to maintenance operations, discriminating between two possible levels of importance, these two levels being critical and non-critical, for critical operations, the monitoring system leaves control of each nuclear reactor to the control system or to the respective operating personnel of each of said nuclear reactors, and simply collects the measured data, while for non-critical operations, the monitoring device can deliver instructions or commands to the respective control systems of the reactors nuclear corresponding to a standard planning of maintenance operations defined for a selected standard nuclear reactor.

The advantages of the invention are numerous:

- The progress and results of maintenance operations are recorded and analyzed.

- Certain simple operations such as elementary tests or the reading of measurements or parameters are automated in order to minimize the risk of human error due to the repetitiveness of the tasks carried out.

-It is possible for a single team to monitor multiple nuclear reactors, thus reducing the costs of monitoring large reactor fleets.

- The system is secure to ensure that no computer bugs endanger the critical functions of the reactors, as well as to ensure better resistance to acts of hacking.

PRESENTATION OF FIGURES

Other characteristics and advantages of the present invention will become apparent on reading the following description of a preferred embodiment. This description will be given with reference to the accompanying drawings in which:

- Figure 1 is a diagram of a general architecture of a control device according to the invention;

FIG. 2a is a diagram of a centralized architecture of a control device according to the invention;

FIG. 2b is a diagram of a distributed architecture of a control device according to the invention.

DETAILED DESCRIPTION OF THE INVENTION Architecture

Referring to Figure 1, a control device, DC, of several nuclear reactors, dedicated to monitoring and maintenance is organized according to the following general architecture: - n nuclear reactors Rl to Rn, each controlled via a dedicated control system (SC-1 to SC-n), in particular these nuclear reactors can be small modular reactors;

- An S-SURV monitoring system, intended to retrieve the data measured by the sensors of each reactor, including a database of the state of the reactors, BDD-E, making it possible to store the history of the values measured by the sensors , as well as commands sent to all the components of the reactor;

- An S-PLAN maintenance operations planning system, intended to assist the personnel in charge of the reactors in the monitoring and maintenance of the reactors, including a database of maintenance operations BDD-OP, making it possible to store information on the maintenance and monitoring operations to be carried out. The planning system also has a human-machine interface (HMI) either in the form of an independent device comprising screens as well as information entry equipment, or in the form of software or a Web application usable from a computer or a touchscreen tablet.

This architecture can be implemented either centrally or in a distributed manner.

With reference to FIG. 2a, in the case of a centralized architecture, a centralized control device, DC-c, is used. This DC-c centralized control device is made up of:

- a centralized monitoring system S-SURV-c, which may consist of one or more computer servers, responsible for processing the data collected on each of the reactors Rl to Rn, by their associated control systems, SC-1 to SC-n. The S-SURV-c centralized surveillance system also includes the BDD-E database which can be either integrated in the form of one or more separate servers in communication with the S-SURV-c centralized surveillance system via a network. private local (LAN) with a star topology, or be installed on the same servers as the rest of the S-SURV-c centralized monitoring system;

- an S-PLAN-c centralized maintenance operations planning system, which may be made up of one or more computer servers, responsible for monitoring and organizing the maintenance operations carried out on all the reactors controlled by the device. This system is connected to the centralized monitoring system S-SURV-c by a private local area network (LAN) with a preferably star topology. The BDD-OP database can either be integrated in the form of one or more separate servers in communication with the centralized maintenance operations planning system S-PLAN-c via a private local area network (LAN), or be installed on the same servers as the rest of the S-PLAN-c centralized maintenance planning system.

It is also perfectly possible that the two systems (monitoring and planning) are combined in a single server.

The control device DC-c is linked to the control systems SC-1 to SC-n by a wide area network 10 such as a data exchange network. This network may preferably be a private data exchange network in order to ensure the security of the connected equipment, such as an "intranet" network via which encrypted data pass either by a symmetric cryptography method (such as AES, DES, Triple DES, etc.), or by an asymmetric cryptography method (such as RSA encryption), in order to ensure the security of the installations connected to the data exchange network. As part of the use of an asymmetric cryptography method, security associations are created before each data exchange between the centralized control device DC-c, and the control systems SC-1 to SC-n reactors. These security associations are based on security elements enrolled a priori in each party (DC-c, SC-n) such as large symmetric keys or certificates binding the identity of the parties in an unfalsifiable manner with a public key. asymmetric. With reference to FIG. 2b, in the case of a distributed architecture, a set of distributed control devices, DC-1 to DC-n, is used. These distributed control devices DC-1 to DC-n are each associated with a reactor. Each distributed control device identified by DC-i is made up of:

- a distributed monitoring system S-SURV-i, which may consist of one or more computer servers, responsible for processing the data collected on the reactor Ri to which it is associated, by the associated control system, SC-i . The S-SURV-i distributed surveillance system further includes the BDD-E database which can be either integrated in the form of one or more separate servers in communication with the S-SURV-i distributed surveillance system via a network. private local (LAN) with a fully meshed topology to ensure better redundancy and thus more security, or be installed on the same servers as the rest of the S-SURV-i distributed surveillance system. In this embodiment, the BDD-E database is a distributed database, i.e. the content of each instance of the database is the same, and includes the data measured on all of the data. reactors monitored. Thus, when new data is added to one of the instances of the database or when existing data is modified or deleted from one of the instances of the database, this transaction is notified to the other instances and the information relating to the addition, deletion or modification are transmitted to the other instances by a wide area network 10 such as a data exchange network. This network can either be a private data exchange network of the intranet type in order to ensure the security of the connected equipment, via which encrypted data passes or by a symmetric cryptography method (such as AES, DES, Triple DES ciphers). etc.), or by an asymmetric cryptography method (such as RSA encryption), in order to ensure the security of the installations connected to the data exchange network. When using a symmetric or asymmetric cryptography method, associations of security are created before each data exchange between the distributed control devices, DC-1 to DC-n, and the SC-1 to SC-n control systems of the reactors. These security associations are based on security elements enrolled a priori in each party (DC-1 to DC-n, and SC-1 to SC-n) such as large symmetric keys or certificates binding in a tamper-proof manner. the identity of the parties with an asymmetric public key;

- a distributed maintenance operations planning system S-PLAN-i, which can be made up of one or more computer servers, responsible for monitoring and organizing the maintenance operations carried out on the reactor with which it is associated. This system is connected to the distributed surveillance system S-SURV-i by a private local area network (LAN) preferably with a fully meshed topology. The BDD-OP database can either be integrated as one or more separate servers in communication with the S-PLAN-i distributed maintenance planning system via a private local area network (LAN), or be installed on the same servers as the rest of the S-PLAN-i distributed maintenance planning system. In this embodiment, the BDD-OP database is a distributed database, that is to say that the content of each instance of the database is the same, and includes the data measured on all of the data. reactors monitored. Thus, when new data is added to one of the instances of the database or when existing data is modified or deleted from one of the instances of the database, this transaction is notified to the other instances and the information relating to the addition, deletion or modification are transmitted to the other instances by a wide area network 10 such as a data exchange network. This network can either be a private data exchange network to ensure the security of connected equipment, via which encrypted data passes or by a symmetric cryptography method (such as AES, DES, Triple DES, etc.) , or by a method asymmetric cryptography (such as RSA encryption), in order to ensure the security of installations connected to the data exchange network;

Finally, it is also possible to hybridize the two types of architectures, this possibility proves to be particularly relevant when it is desired to control reactors present in several copies on different sites. In this case, all the reactors present on the same site can be controlled by a centralized control device, and this centralized system itself forming part of a distributed control device.

Operation of the monitoring system

At any time or periodically, the monitoring system is responsible for measuring and recording all the state and operating parameters of the reactor and its installation, these operating parameters being for example:

- Temperatures, pressures, flow rates, levels, power, chemistry, control parameters etc. the reactor and its auxiliary circuits;

- The neutron parameters of the core: neutron power, power distribution, position of the control clusters, soluble boron concentration

- The state and the operating parameters of the turbo-alternator group, the water station, the electrical network;

- Measurements carried out on the installation or on the site; weather forecast, heat sink temperature, radiation protection;

- Measurements of vibrations, performance or number of stresses

- Etc.

These operating parameters are recorded in the database of the state of nuclear reactors with a certain time step (for example of the order of a second) and thus make it possible to identify the malfunction of a component, to be able to check the history of operation in the event of a technical incident as well as developing models to predict the future state of the reactor or its components.

How the planning system works

The planning system for its part aims to ensure the robustness of the reactor maintenance process, these maintenance operations being either operations carried out by the operating personnel or tests carried out automatically by the equipment itself (for example an automatic sequence, availability or performance test of a system). To do this, it includes a database of maintenance operations in which are recorded all the maintenance operations to be carried out on all the reactors as well as, for each maintenance operation, a deadline by which the operation must be carried out and a information making it possible to identify the reactor on which the maintenance operation must be carried out. In addition, when a maintenance operation has been performed, a record is added to the database, either by operating personnel or reports generated automatically as a result of the operations.

These records can be made in the form of forms filled in by the operating personnel via portable terminals securely connected to the distributed communication network, and making it possible to validate or fill in the maintenance operations carried out.

The planning system manages the maintenance operations which must be carried out periodically (eg every two months, every year etc.). The planning system can also add maintenance operations to be carried out according to the results of the maintenance operations previously carried out, the operating history of the reactor, the values of the operating parameters or else according to the evolution of these. values or according to lessons learned from other reactors (experience feedback). For example, if the planning system detects vibrations abnormally high in the turbine, the planning system may automatically add a turbine condition check operation to the database. Likewise, the planning system can add maintenance operations to be carried out when it detects excessively high temperature values, abnormal pressure variations, component malfunction, or even in the event of an incident occurring. is produced on a neighboring reactor and which would require verifications to be carried out on the other reactors. The planning system can trigger an additional automatic operation or else to be carried out by the operating personnel.

Level of criticality

Due to the sensitivity of the equipment under its control, the reactor control system must have information on the importance of the components it monitors to the proper functioning of the reactors in order to know how to monitor them. For this, two levels of importance are attributed to maintenance operations as well as to reactor components: "critical" when the operation or component is of critical importance for the correct functioning of the reactor and "non-critical" otherwise. . These levels of importance make it possible to identify which components of the reactor, or which maintenance operations require more attention, for example by requiring the intervention of a qualified supervisor, by allowing only software components that have been used. 'subject to formal verification (for example by static analysis methods) to treat the components or operations identified as "critical", or else by simply collecting the measured data. It is also possible to only allow the device to supervise “non-critical” maintenance operations and to leave the control of all “critical” maintenance operations to the respective control systems of each of the reactors, and thus make the operations of "critical" maintenance independent of the planning system. Maintenance operations that can be qualified as "Critical" are those related to systems, structures or components related to safety, environment, security or availability such as:

- The reactor in operation;

- reactor safety or safeguard systems;

- the reactor protection system;

- classified auxiliary systems:

. ventilation,

. control command,

. electrical distribution,

. emergency diesel,

. refrigeration systems,

. the pumping station, and. containment;

- the turbo-alternator unit and its auxiliaries for operation:

. the condenser,

. the water station,

. the cooling circuit,

. the transformer, and. the evacuation station

These components are classified as "critical".

Conversely, maintenance operations that can be qualified as “non-critical” are those related to other structural systems or components such as:

- adjustment of load or frequency setpoints (remote setting);

- treatment of effluents and waste;

- the demineralization station;

- the production of auxiliary steam;

- site works;

- general services.

These components are not classified as "critical". Improvement of the device over time

The collection of data carried out such as physical measurements relating to a set of physical parameters, a precise estimate of the temporal revolution of at least one of these measurements (temperature of the cooling circuit, current-voltage at the secondary, etc.) by the systems monitoring and planning is used to improve the detection of malfunctions as well as to identify the actions to be taken following the detection of an anomaly. Indeed, the data recorded in the database of the state of nuclear reactors can be combined with the data recorded in the database of maintenance operations, and more particularly the reports on the progress of maintenance operations allow for example to establish relationships between the values read by the sensors of the reactors and the state of a component, or to predict the outcome of a test by applying machine learning methods. For example by training a machine learning model to detect abnormal drift of at least one of the parameters measured using recurrent neural networks, for example LSTM (long short-term memory) type models , GRU (gated recurrent unit), bidirectional recurrent networks. The use of such models makes it possible, among other things, to detect malfunctions which are not detected by simpler methods such as tolerance margins associated with the parameters. The detection of malfunctions thus makes it possible to program new inspection operations or new automatic tests to be carried out when the control device identifies a risk of malfunction.

Management of a group of nuclear reactors

In order to simplify the management of the reactors by the operating teams, a method is also proposed which consists in modifying certain operating parameters of the reactors so that all the reactors in a group of nuclear reactors operate in an efficient manner. similar, for example same load level, similar temperatures, close water flow rate at the outlet of a pump etc. This thus makes it possible to have similar levels of wear of the components on all the reactors of the group of nuclear reactors, and thus to be able to predict the state of the components of a reactor as a function of the other reactors of the group, for example. if a component fails on a reactor, the control device will automatically program the inspection of this component on all the reactors with similar operating parameters. This also allows “interdependent” operation of a group of reactors, for example in order to distribute the load or the response to load transients called up by the network between the reactors: the reactor which will be the most maneuvering will be requested as a priority, sparing the reactors which could be in a more difficult situation to maneuver (because at the end of the cycle, or in stable operation to carry out tests), compensation of a reactor in difficulty (or in incident) by the others, etc.

This adjustment of the operating parameters is also associated with an algorithm for creating groups of reactors. This algorithm, based on classical data partitioning methods (clustering) creates partitions of all nuclear reactors, these partitions being called platoons. Once a platoon has been created, it is always possible to add a new reactor or to exclude a reactor belonging to the platoon, depending on the values of the operating parameters. Thus, if a reactor is subject to a much higher production demand than the other reactors in the peloton, it could be excluded or else reassigned to a new more suitable group. For this, acceptable variation margins are associated with each operating parameter of the reactors, in order to make it possible to decide whether a given reactor can remain in its platoon or if it must change.

Claims

1. Device for controlling a plurality of nuclear reactors, comprising for each nuclear reactor a plurality of sensors intended to measure operating parameters and a nuclear reactor control system, characterized in that it further comprises:

a system for monitoring the state of each nuclear reactor, in communication with all of the sensors of the plurality of nuclear reactors, and comprising a database of the state of nuclear reactors, the database of the state of nuclear reactors comprising, for at least one nuclear reactor and for at least a given instant, data relating to: the level of use of the nuclear reactor, the use of the components of the nuclear reactor, the operating parameters of the nuclear reactor , the state of the nuclear reactor fuel, the planned changes in the rate of utilization of the nuclear reactor; and

. a maintenance operation to be carried out,

. a nuclear reactor on which the maintenance operation must be carried out,

. a time and date on which this operation must be carried out, device in which a level of importance for the proper functioning of each nuclear reactor is assigned to maintenance operations, the level of importance being critical and non-critical, for critical operations, the monitoring system leaves control of each nuclear reactor to the control system or to the respective operating personnel of each of said nuclear reactors and collects the data measured by the sensors of the nuclear reactors, while for non-critical operations the monitoring system issues instructions or commands to the respective control systems of the nuclear reactors for critical operations as well as non-critical operations, the breadmaking system transmits to the nuclear reactors a planning of maintenance operations corresponding to a standard planning of operations maintenance defined for a selected standard nuclear reactor, or a personalized schedule for each nuclear reactor according to its status and the data recorded in the nuclear reactor status database.

2. Device for controlling a plurality of nuclear reactors according to claim 1, characterized in that it comprises a single central monitoring system of the state of all the nuclear reactors.

3. Device for controlling a plurality of nuclear reactors according to one of claims 1 and 2, characterized in that it comprises a single central planning system for the maintenance operations of all the nuclear reactors.

4. Device for controlling a plurality of nuclear reactors according to claim 1, characterized in that it comprises a dedicated monitoring system for each nuclear reactor according to a distributed architecture.

5. Control device for a plurality of nuclear reactors according to claim 4, characterized in that all of the monitoring systems of each nuclear reactor communicate via a network. exchange of data in order to update the database of the state of the nuclear reactors of each monitoring system according to the evolution of the state of the other nuclear reactors of the plurality of nuclear reactors.

6. Device for controlling a plurality of nuclear reactors according to claim 5, characterized in that each nuclear reactor communicates with the control device via a data exchange network via an independent communication link which has been the subject of a security association prior to data exchanges, guaranteeing the confidentiality, authentication and integrity of the communication.

7. Device for controlling a plurality of nuclear reactors according to one of claims 1 and 2, characterized in that it comprises a dedicated maintenance operations planning system for each nuclear reactor according to a distributed architecture.

8. Device for controlling a plurality of nuclear reactors according to claim 7, characterized in that all of the maintenance operations planning systems for each nuclear reactor communicate via a data exchange network in order to update. the database of maintenance operations for each monitoring system as a function of planned maintenance operations for the other nuclear reactors of the plurality of nuclear reactors.

9. Device for controlling a plurality of nuclear reactors according to claim 8, characterized in that each nuclear reactor communicates with the others via a data exchange network via an independent communication link which has made the subject of a security association prior to data exchanges, guaranteeing the confidentiality, authentication and integrity of the communication.

10. Device for monitoring a plurality of nuclear reactors according to one of claims 1 to 9, characterized in that the nuclear reactors of the plurality of nuclear reactors are small modular reactors.

11. Device for controlling a plurality of nuclear reactors according to one of claims 1 to 10, characterized in that the maintenance operations to be carried out are either inspection operations of an element of a nuclear reactor by a operating personnel of one of the nuclear reactors, that is, tests carried out automatically by the control system of a nuclear reactor.

12. Device for controlling a plurality of nuclear reactors according to one of claims 1 to 12, characterized in that the critical maintenance operations are the maintenance operations which relate to the systems, structures or components related to safety, l 'environment, security or availability, said systems, structures or components relating to safety, environment, security or availability including

- the reactor in operation;

- reactor safety or safeguard systems;

- the reactor protection system;

- classified auxiliary systems, said classified auxiliary systems comprising:

. ventilation,

. control command,

. electrical distribution,

. emergency diesel,

. refrigeration systems,

. the pumping station, and

. containment;

- the turbo-alternator unit and its auxiliaries for operation, said turbo-alternator unit and its auxiliaries for operation comprising:

. the condenser,

. the water station,

. the cooling circuit,

. the transformer, and. the evacuation station.

13. Device for controlling a plurality of nuclear reactors according to claim 12, characterized in that the non-critical maintenance operations include the related maintenance operations:

- adjusting the load or frequency setpoints;

- treatment of effluents and waste;

- at the demineralization station;

- the production of auxiliary steam;

- site works;

-general services.

14. Device for controlling a plurality of nuclear reactors according to one of claims 1 to 13, characterized in that when a maintenance operation to be carried out is a test carried out automatically by the control system of a nuclear reactor, the command to start the test process is sent directly by the control device.

15. Device for controlling a plurality of nuclear reactors according to one of claims 1 to 14, characterized in that when a maintenance operation to be carried out is an inspection operation of an element of a nuclear reactor by operating personnel, the control device sends a notification to the address of the operating personnel indicating the inspection operation of a nuclear reactor element to be carried out, the nuclear reactor concerned, as well as the time remaining before the time and date on which the inspection operation of a nuclear reactor element must be carried out.

16. Device for controlling a plurality of nuclear reactors according to one of claims 1 to 15, characterized in that following the performance of a maintenance operation, a recording of the progress of the maintenance operation is added to the data relating to the maintenance operation.

17. Device for controlling a plurality of nuclear reactors according to claim 16, characterized in that the report on the progress of the maintenance operation comprises, in the case of a test carried out automatically, a recording of the progress of the operation. maintenance operation and information relating to the test results.

18. Device for controlling a plurality of nuclear reactors according to claim 16, characterized in that the report on the progress of the maintenance operation comprises, in the case of an inspection of an element of the nuclear reactor, a information relating to the state of the inspected nuclear reactor component.

19. Device for controlling a plurality of nuclear reactors according to one of claims 16 to 18, characterized in that data relating to additional maintenance operations are added automatically following the addition of a report on the progress. from a maintenance operation to data relating to the maintenance operations.

20. Device for controlling a plurality of nuclear reactors according to claim 18, characterized in that the planning system of maintenance operations learns, during its operation, which additional maintenance operations are to be added automatically according to the contents of the report on the progress of a maintenance operation.

21. Device for controlling a plurality of nuclear reactors according to claim 20, characterized in that the learning carried out by the maintenance operations planning system comprises the analysis of the content of all the reports on the progress of the reactor. a maintenance operation recorded by the maintenance operations planning system in the maintenance operations database in order to determine new maintenance operations or changes in the frequency at which certain maintenance operations must be carried out.

22. Device for controlling a plurality of nuclear reactors according to claim 20, characterized in that the learning carried out by the maintenance operations planning system comprises the training of an artificial learning model from the data. recorded by the maintenance operations planning system in the maintenance operations database in order to determine an optimal maintenance strategy.

23. A method of controlling a plurality of nuclear reactors, comprising, for each nuclear reactor, steps of measuring operating parameters using a plurality of sensors and controlling said nuclear reactor, characterized in that it comprises in addition the steps which consist of:

- monitoring the state of each nuclear reactor, on the basis of the information provided by all the sensors of the plurality of nuclear reactors, and on the basis of information contained in a database of the state of the nuclear reactors, the reactor condition database nuclear comprising, for at least one nuclear reactor and for at least a given instant, data relating to:

. at the level of use of the nuclear reactor,

. the use of nuclear reactor components,

. the operating parameters of the nuclear reactor,

. the state of the nuclear reactor fuel,

. a maintenance operation to be carried out,

. a nuclear reactor on which the maintenance operation must be carried out,

. a time and a date at which this operation must be carried out.

24. The method of claim 23, characterized in that it comprises the steps of finding a level of importance for the proper functioning of each nuclear reactor assigned to maintenance operations, discriminating between two possible levels of importance, these two levels being critical and non-critical, for the critical levels leave the control of each nuclear reactor to a respective control system of each of said nuclear reactors, while for non-critical levels the monitoring process imposes on the respective control systems nuclear reactors a planning of maintenance operations corresponding to a standard planning of maintenance operations defined for a selected standard nuclear reactor.