FR3129015A1 - Method for certifying the consumption of a quantity of electrical energy supplied by an electrical outlet - Google Patents

Abstract

The invention proposes a method, implemented by an electrical outlet (2) connected to an electrical network (3), for certifying the consumption of a quantity of electrical energy supplied by the outlet (2) and consumed by a electrical device (4) connected to the socket (2), the electrical socket being further connected to a distributed database (12) with a chain of blocks (24), each block of the chain (24) containing data representative of one or more electrical energy transactions, the method comprising at least one step of storing a current chain of blocks, and the following steps: - supplying a predetermined quantity of electrical energy to said electrical device (4) ; - an addition of a new block to the current chain of blocks (24), thus forming a new chain of blocks, said new block containing data representative of an electrical energy transaction; - a transmission of the new chain of blocks (24) to the distributed database. Figure of the abstract: Figure 2

Description

Method for certifying the consumption of a quantity of electrical energy supplied by an electrical outlet

Field of invention

The invention relates to a method, implemented by an electrical outlet connected to an electrical network, for certifying the consumption of a quantity of electrical energy supplied by the outlet and consumed by an electrical device connected to the outlet. The invention also relates to an electrical outlet for the implementation of such a method.

State of the art

In the context of the energy transition towards less carbon-intensive energies, there is a need to be able to certify, with an intermediate or final consumer of the energy supplied, the origin and/or the nature of this energy. Energy suppliers are thus expected by their customers, suppliers, public partners, distributors, investors and employees on their concrete positions to support these changes in energy sources.

In this context, a known solution to meet the aforementioned need consists of a certification mechanism by guarantees of origin. A guarantee of origin is an electronic document used to prove to an end consumer that a part or a quantity of electrical energy has been produced from renewable energy sources or by cogeneration. Legally, the guarantee of origin is the only document guaranteeing the origin of the electricity consumed. Guarantees of origin are thus electronic certificates issued to electricity producers in proportion to the quantity of electricity produced from renewable energy sources. Guarantees of origin trace, for example, the origin of so-called "green" electrical energy, i.e. from one or more renewable energy source(s), from the producer to the final consumer, thus ensuring the transparency of the origin of the electricity to this consumer. In particular, there is a European system for traceability of the origin of the electricity produced and supplied, namely European Directive No. 2009/28/EC, as well as an energy code and a register for the management of guarantees. of origin.

Thus, in the European Union, energy suppliers who market so-called “green” electricity offers must have a volume of guarantees of origin equivalent to the level of consumption of their customers who have subscribed to these offers. Guarantees of origin can be exchanged independently of the electricity they certify. Energy suppliers can thus buy electricity and guarantees of origin directly from “green” energy producers by signing purchase contracts with them or – more frequently – buying electricity on the market. and guarantees of origin independently. In concrete terms, a guarantee of origin is an electronic certificate corresponding to 1 MWh of electricity from renewable sources.

In France, electricity suppliers must now ensure the balance between their customers' so-called "green" electricity consumption and the volume of guarantees of origin on a monthly basis and no longer on an annual basis as before. In each guarantee of origin, a great deal of information concerning the installation in which the electricity was produced is indicated: location, capacity, date of entry into service of the installation, aid from which the installation benefits, etc. To receive one or more guarantees of origin, an electricity producer must hold an account in a national registry. Other players wishing to exchange guarantees of origin can also register in this register. Non-producing electricity suppliers can thus, thanks to this mechanism, offer their customers so-called “green” electricity offers.

However, the use of such a mechanism of certification by guarantees of origin is relatively tedious, not very flexible and generates management and processing times that are very often long. In addition, the register used to manage guarantees of origin is likely, by its very nature (often a database maintained by a public or private body), to be compromised by malicious actors. Finally, the mechanism of certification by guarantees of origin does not make it possible to certify the consumption of a quantity of energy in an instantaneous, dynamic and flexible way, and imposes for a consumer to go through traditional energy distributors.

The object of the invention is to propose a method, implemented by an electrical outlet connected to an electrical network, making it possible to certify in a simple, flexible, rapid and dynamic manner the consumption of a quantity of electrical energy supplied by the socket and consumed by an electrical device connected to the socket, while presenting improved reliability and security (in particular vis-à-vis any attempt at compromise).

• au moins une étape de stockage, par les moyens mémoire de la prise électrique, d’une chaîne de blocs courante issue de la base de données distribuée ;
• une fourniture, par la prise électrique, d’une quantité d’énergie électrique prédéterminée audit appareil électrique, ladite quantité d’énergie électrique prédéterminée étant prélevée sur le réseau électrique ;
• un ajout, par les moyens de traitement, d’un nouveau bloc à la chaîne de blocs courante, formant ainsi une nouvelle chaîne de blocs, ledit nouveau bloc contenant des données représentatives d’une transaction d’énergie électrique, la transaction correspondant à ladite quantité d’énergie électrique prélevée sur le réseau électrique et fournie par la prise électrique à l’appareil électrique ;
• une transmission, par la prise électrique, de la nouvelle chaîne de blocs à la base de données distribuée, ladite transmission étant effectuée sur le réseau de communication de données.

For this, the invention proposes a method, implemented by an electrical outlet connected to an electrical network, for certifying the consumption of a quantity of electrical energy supplied by the outlet and consumed by an electrical device connected to the outlet, the electrical outlet being further connected, via a data communication network, to a distributed block chain database, each block of the block chain containing data representative of one or more electrical energy transactions, the electrical outlet comprising memory means and processing means connected to the memory means, the memory means being configured to store said chain of blocks, the method comprising the following steps:

• at least one step of storing, by the memory means of the electrical socket, a current chain of blocks coming from the distributed database;
• a supply, via the electrical outlet, of a predetermined quantity of electrical energy to said electrical device, said predetermined quantity of electrical energy being taken from the electrical network;
• an addition, by the processing means, of a new block to the current chain of blocks, thus forming a new chain of blocks, said new block containing data representative of an electrical energy transaction, the transaction corresponding to said quantity of electrical energy taken from the electrical network and supplied by the electrical outlet to the electrical appliance;
• a transmission, via the electrical socket, of the new chain of blocks to the distributed database, said transmission being carried out over the data communication network.

The method according to the invention makes it possible to certify in a simple, flexible, rapid and dynamic manner the consumption of a quantity of electrical energy supplied by the socket and consumed by an electrical device connected to the socket. In addition, thanks to the use by the electrical outlet of a chain of blocks (or “blockchain” in English) resulting from a distributed database with a chain of blocks, the method according to the invention has reliability and a improved security compared to the certification methods of the prior art. Indeed, each transaction validated by the members of a community relating to the distributed database is integrated into the chain in the form of a block, and is therefore impossible to corrupt because it is shared at all times by all the members. This configuration guarantees the integrity of evidence for everyone. Thanks to this use of a chain of blocks by the electrical socket, the latter can register reliably and securely, in the information chain, all the characteristics specific to a quantity of electrical energy supplied by the socket and consumed by the electrical appliance connected to the socket. The method according to the invention thus makes it possible to certify almost instantaneously the consumption of a given quantity of electrical energy, and to allow a reconciliation between the origin and/or the nature of this quantity of electrical energy and its consumption. , typically in a digital register, dynamic, incorruptible and accessible to all.

The method according to the invention also makes it possible to provide an instantaneous electricity consumption load curve. The method can thus advantageously be part of a broader method aimed at bringing this (certified) instantaneous electricity consumption load curve closer to an electricity production load curve provided for example by a third-party operator (and certified by this operator) . An aggregator can then manage, for example, the signatures of the electricity produced and consumed by superimposing the instantaneous electricity consumption load curve (certified) and the electricity production load curve (certified). The method according to the invention thus saves time and reduces costs. The synchronization between the production of electricity and the certification of the associated consumption, attested and stored in the shared chain, then offers greater transparency and better traceability of energy for the user, while allowing the latter to compose its own energy mix in accordance with its convictions. The method according to the invention also provides greater flexibility of use to users, as well as new uses for the latter: thanks to the method according to the invention, each electricity producer (whether it is a company or an individual - whose house is equipped with solar panels, for example) can thus make available the surplus electricity it produces, without going through traditional distributors, in a peer-to-peer configuration ( or “peer-to-peer” in English). Everyone thus becomes a player in the energy transition, by choosing much more precisely the energy they consume, and by therefore participating in the overall approach towards less carbon-intensive energies (and more renewable in proportion in the energy mix). The use of a chain of blocks by the method according to the invention finally makes it possible to precisely measure the distribution of energy and to monitor compliance with the distribution keys in a very dynamic way.

• un stockage, par les moyens mémoire, d’une chaîne de blocs courante initiale issue de la base de données distribuée ;
• une réception, par les moyens de traitement, d’une requête de consommation de ladite quantité d’énergie électrique prédéterminée, ladite requête correspondant à une demande de consommation de ladite quantité d’énergie électrique par l’appareil électrique relié à la prise, ladite requête comprenant une transaction d’énergie électrique signée électroniquement ;
• une validation, par les moyens de traitement, de la signature électronique de ladite transaction d’énergie électrique ;
• un ajout, par les moyens de traitement, d’un nouveau bloc à la chaîne de blocs courante initiale, formant ainsi une nouvelle chaîne de blocs, ledit nouveau bloc contenant des données représentatives de ladite transaction d’énergie électrique ;
• une transmission, par la prise électrique, de la nouvelle chaîne de blocs à la base de données distribuée, ladite transmission étant effectuée sur le réseau de communication de données.

According to a particular technical characteristic of the invention, the method further comprises the following steps, carried out before the step of supplying, via the electrical outlet, a predetermined quantity of electrical energy to said electrical device:

• storage, by the memory means, of an initial current chain of blocks originating from the distributed database;
• a reception, by the processing means, of a request to consume said predetermined quantity of electrical energy, said request corresponding to a request to consume said quantity of electrical energy by the electrical appliance connected to the socket, said request comprising an electronically signed electrical energy transaction;
• validation, by the processing means, of the electronic signature of said electrical energy transaction;
• an addition, by the processing means, of a new block to the initial current chain of blocks, thus forming a new chain of blocks, said new block containing data representative of said electrical energy transaction;
• a transmission, via the electrical socket, of the new chain of blocks to the distributed database, said transmission being carried out over the data communication network.

According to a particular technical characteristic of the invention, during the step(s) of adding a new block to the current chain of blocks, the processing means of the electrical socket also add in the new block a sum control of the electrical energy transaction(s) of which said block is representative. The addition of such a checksum allows the identification of the block and therefore of the corresponding electrical energy transaction.

According to a particular technical characteristic of the invention, during the step(s) of adding a new block to the current block chain, said data representative of the electrical energy transaction(s) contain in addition an electronic signature representative of the decision.

According to a particular technical characteristic of the invention, a public address is associated with the electrical socket in the distributed blockchain database, and the memory means of the electrical socket are configured to store a private encryption key associated with the outlet, said private encryption key being configured to cooperate with said public address to allow manipulation of said public address by a user of the electrical outlet.

According to a particular technical feature of the invention, the data communication network is a private blockchain network compliant with the Ethereum protocol, and in that the blockchain distributed database is compliant with the Ethereum protocol.

Advantageously, the distributed blockchain database complies with the DLT (Distributed Ledger Technologies) distributed ledger protocol. This improves the transparency and security of the network, because it is more difficult to compromise than a centralized database. Such a protocol effectively defines a digital system that records asset transactions and their details in multiple locations at once. Unlike traditional databases, such a digital DLT system does not have a reference data repository or storage or a centralized administration function. In a DLT distributed ledger, each node in a network (typically a network of computers) processes and validates transactions simultaneously. Such a register is thus simultaneously recorded and synchronized on the nodes of the network. A consensus on the veracity of the registry changes or modifications is then found between the different nodes, which must vote to ensure the security and legitimacy of each update. A peer-to-peer network and a consensus algorithm are thus necessary in order to ensure the functioning of the system.

According to another aspect, the invention also relates to an electrical outlet intended to be connected on the one hand to an electrical network, and on the other hand to a distributed database with block chains via a data communication network, the electrical outlet comprising memory means and processing means connected to the memory means, the memory means being configured to store said chain of blocks, the electrical outlet being configured to implement the method for certifying the consumption of a quantity of electrical energy as described above.

Advantageously, the processing means and the memory means of the electrical socket are in the form of a crypto-authentication chip, said crypto-authentication chip storing a private encryption key associated with the socket, said private encryption key being configured to cooperate with a public address associated with the electrical outlet in the distributed blockchain database, to allow manipulation of said public address by a user of the electrical outlet. This makes it possible to improve the security of the transactions carried out by the electrical socket in the context of the certification of the consumption of a quantity of electrical energy, by substantially reducing the risk of compromise of the data contained in the electrical socket. Such a crypto-authentication chip makes it possible to lock the private encryption key associated with the socket in complete security. Once the private encryption key is stored in the chip, it cannot be read by an unauthorized third party: only “challenge-response” requests can be sent.

Preferably, the crypto-authentication chip is a single-board nanocomputer with an ARM (Advanced RISC Machines) processor. Such an ARM processor is based on a RISC reduced instruction set computer architecture. The ARM-based single-board nanocomputer is, for example, an RPI (Raspberry Pi) cryptology module.

Brief description of figures

The aims, advantages and characteristics of the method for certifying the consumption of a quantity of electrical energy according to the invention will appear better in the following description on the basis of at least one non-limiting embodiment illustrated by the drawings. on which ones :

, there is a schematic representation of an assembly comprising several electricity production sources and an electrical outlet according to the invention, the electricity production sources and the electrical outlet being connected to a common electrical network;

, there is a schematic representation of one embodiment of the electrical outlet of the , for the implementation of a method for certifying the consumption of a quantity of electrical energy supplied by the socket and consumed by an electrical device connected to the socket;

, there is a flowchart representing the method for certifying the consumption of a quantity of electrical energy according to one embodiment of the invention; And

is a sequence diagram illustrating several steps in the process of .

In the rest of the description, the term “origin of electrical energy” is understood to mean a set of information grouping together the electrical energy production site, its producer, and/or the date and time of production of this energy.

The term "nature of electrical energy" also means the renewable or non-renewable nature of the primary energy source used to produce this electrical energy, and/or the type of primary energy source to which it refers. Typically, and without this being limiting, for a non-renewable energy source, a distinction is made between fossil-type energies (example: coal, gas, oil, etc.) or fissile (example: uranium); and for a renewable energy source, we can distinguish wind energy, solar energy, hydraulic energy or geothermal energy.

Finally, "certification of the consumption of a quantity of electrical energy" means an authenticated signature of the electrons consumed by an electrical device connected to the socket, at a given location (namely the place where the socket is installed), the set of electrons consumed defining the quantity of electrical energy.

In the following, there is disclosed in particular a method, implemented by an electrical outlet 2 connected to an electrical network 3, for certifying the consumption of a quantity of electrical energy supplied by the outlet 2 and consumed by a device 4 connected to the socket 2. Without this being limiting in the context of the present invention, the electrical device 4 is typically a rechargeable electric or hybrid vehicle, and the electrical socket 2 is then intended to allow the electric recharging of a traction battery of the vehicle 4. The electrical outlet 2 has intrinsic characteristics allowing it to deliver an electric current of intensity for example substantially equal to 16 Amps for several hours. The electric recharging of the traction battery of the vehicle 4 via socket 2 is typically a slow recharging, for example a recharging of approximately 8 hours for a full charge of a traction battery having a nominal power of approximately 22 kW. The electrical outlet 2 is for example permanently installed in a building, a dwelling, or even a garage.

There represents an assembly 6 comprising the electrical outlet 2, as well as several sources of electricity production 8a - 8e connected to the electrical network 3. Five sources of electricity production 8a - 8e are represented in the particular embodiment of the , which come respectively from five primary energy sources divided between a nuclear energy source, a wind energy source, a solar energy source, a hydraulic energy source and a source of an energy at coal.

Set 6 makes it possible to certify electricity production from electricity production sources 8a – 8e, and to reconcile this certified electricity production with instantaneous electricity consumption, the latter being certified by the electrical outlet 2 according to the invention. Thus, certified production signatures 5, corresponding to electricity production sources 8a-8e, are transmitted to an aggregator 7. These production signatures 5 certify the origin and/or the nature of the electrical energy produced by the power generation sources 8a – 8e. Consumption signatures certified 9 by the electrical outlet 2 are also transmitted by the outlet 2 to the aggregator 7. The aggregator 7 manages the various signatures transmitted to it by superimposing the production load curves and the instantaneous consumption, considering that all the electrons produced have been emitted on the electrical network 3 or self-consumed by producer-consumers.

As illustrated on the , in addition to the electrical network 3, the electrical outlet 2 is also connected, via a data communication network 10, to a distributed database 12 with a chain of blocks 24 (or "blockchain" in English). The electrical socket 2 comprises memory means 14 and processing means 16 (typically in the form of one or more processors) connected to the memory means 14. The electrical socket 2 also comprises means of communication on the data communication network 10; such means not being represented in the figures for reasons of clarity and typically comprising at least one of the following elements: a Wi-Fi card, a Li-Fi card, a 4G relay antenna. Preferably, the memory means 14 and the processing means 16 are in the form of a crypto-authentication chip 18. The crypto-authentication chip 18 is advantageously a single-board nanocomputer with an ARM processor “Advanced RISC Machines”), and can typically form an RPI (Raspberry Pi) cryptology module. The memory means 14 of the chip 18 store embedded software (or "firmware" in English) allowing the operation of the chip 18 (such embedded software not being represented on the for reasons of clarity). The on-board software integrates a dedicated protocol which allows a breakdown of the data relating to the electrical outlet 2 and storage of the latter in a Merkel tree. The memory means 14 of the chip 18 also store, preferably, a private encryption key associated with the electrical outlet 2 (such a key not being represented on the ). The private encryption key is configured to cooperate with a public address associated with electrical outlet 2 in the distributed database 12, to allow manipulation of the public address of outlet 2 by a user of outlet 2.

The data communication network 10 is equipped with a private or extended communication infrastructure allowing the connection, or the access, to communication equipment of the type servers and/or databases and/or mobile communication devices. Conventionally, the communication infrastructure forms a wireless network, or a wired network, or even a network comprising a wireless portion and a wired portion. In a particular embodiment, the communication network 10 is designed as a private blockchain network compliant with the Ethereum protocol. In another embodiment, the communication network 10 is designed as comprising an Internet-type network portion and a private blockchain network portion conforming to the Ethereum protocol. The communication network 10 comprises for example a data collection gateway relating to the electrical outlet 2 (such a gateway not being shown in the figures), as well as a cloud computing infrastructure 20 (or "cloud" in English ) making it possible to implement an IoT (Internet of Things) type data communication network.

The distributed database 12 with chain of blocks 24 typically conforms to the DLT (Distributed Ledger Technologies) distributed ledger protocol. As illustrated on the , the distributed database 12 thus comprises a distributed middleware layer 22 conforming to the DLT protocol, as well as a database availability group network DAG (from the English “Database Availability Group » - not shown on the ) connected to data sources other than the electrical outlet 2. Preferably, the distributed database 12 with chain of blocks 24 also complies with the Ethereum protocol.

Each block of the chain of blocks 24 contains data representative of one or more electrical energy transactions, such as for example the financial amount relating to the electrical energy transaction(s) of which the block is representative and/ or a checksum of the electrical energy transaction(s), and/or an electronic signature. Some of the blocks in the chain of blocks 24 may also include the origin and/or the nature of a quantity of electrical energy relating to the transaction(s) of electrical energy concerned.

The method for certifying the consumption of a quantity of electrical energy according to the invention, implemented by the electrical outlet 2, will now be described with reference to Figures 3 and 4.

Preferably, the method comprises an initial step 30 during which the memory means 14 of the electrical outlet 2 store an initial current chain of blocks 24, originating from the distributed database 12. This initial current chain of blocks 24 is by example transmitted over the data communication network 10, from the distributed database 12 to the electrical outlet 2.

Preferably, the method includes a following step 32 during which the processing means 16 of the electrical outlet 2 receive a request 33 to consume a predetermined quantity of electrical energy. The request 33 is for example transmitted to the electrical outlet 2 by a mobile communication device (not shown in the figures) belonging to a user of the outlet 2, and includes an electronically signed electrical energy transaction. The transaction is typically an Ethereum transaction. The request 33 corresponds to a request for consumption of the quantity of electrical energy by the electrical device 4 connected to the electrical outlet 2.

Preferably, the method includes a following step 34 during which the processing means 16 of the electrical outlet 2 validate the electronic signature of the electrical energy transaction contained in the request 33.

Preferably, the method comprises a following step 36 during which the processing means 16 of the electrical socket 2 add a new block to the initial current chain of blocks 24, thus forming a new chain of blocks. The new block added contains data representative of the electric energy transaction contained in the request 33. More precisely, the data representative of the electric energy transaction can for example comprise the quantity of electric energy requested, as well as the amount finance associated with the electrical power transaction. Preferably, the data representative of the electrical energy transaction also contain an electronic signature representative of the electrical outlet 2. Again preferably, during this addition step 36, the processing means 16 of the electrical outlet 2 add also in the new block a checksum of the electrical energy transaction. The addition of this checksum allows the identification of the block and therefore of the corresponding electrical energy transaction. At the end of this addition step 36, the memory means 14 of the electrical outlet 2 store the new chain of blocks as a new current chain of blocks 24.

Preferably, the method comprises a following step 38 during which the electrical outlet 2 transmits, via the data communication network 10, the new current chain of blocks 24 to the distributed database 12.

During a following step 40, the electrical outlet 2 supplies the predetermined quantity of electrical energy to the electrical device 4. To do this, the electrical outlet 2 takes this predetermined quantity of electrical energy from the electrical network 3. The predetermined quantity of electric energy is supplied by one of the electricity production sources 8a-8e, for example by the second source 8b using wind energy as the primary energy source. This second source 8b then transmits to the aggregator 7 a certified production signature 5 corresponding to the quantity of electricity produced and transmitted to socket 2.

During a following step 42, the processing means 16 of the electrical socket 2 add a new block to the current chain of blocks 24, thus forming a new chain of blocks. The new block added contains data representative of the electrical energy transaction carried out. More precisely, the data representative of the electrical energy transaction carried out contain, for example, the date, time and/or amount of this electrical energy transaction. Preferably, the data representative of the electrical energy transaction carried out also contain an electronic signature representative of the electrical outlet 2. Preferably again, during this addition step 42, the processing means 16 of the electrical outlet 2 also add in the new block a checksum of the electrical energy transaction carried out. The addition of this checksum allows the identification of the block and therefore of the corresponding electrical energy transaction. At the end of this addition step 42, the memory means 14 of the electrical outlet 2 store the new chain of blocks as a new current chain of blocks 24.

During a final step 44, the electrical socket 2 transmits, via the data communication network 10, the new chain of current blocks 24 to the distributed database 12. The electrical socket 2 also transmits to the aggregator 7 a certified consumption signature 9 associated with the electrical energy transaction carried out. This certified consumption signature 9 here corresponds to the electronic signature specific to the socket 2. In a practical manner, the electrical socket 2 can forward to the aggregator 7 a certified consumption signature 9, associated with the electrical energy transaction carried out , by directly transmitting the new chain of current blocks 24 to it. In this way, the electrical socket 2 makes it possible to sign the consumption of electrical energy at a given location, namely the location where the socket is installed. The aggregator can then reconcile the certified consumption signature 9 transmitted by socket 2 with the certified production signature 5 transmitted by the second source 8b.

The method according to the invention makes it possible to record reliably and securely, in the information chain, all the characteristics specific to a quantity of electrical energy supplied by the socket and consumed by the electrical appliance connected to the socket. The method thus makes it possible to certify almost instantaneously the consumption of a given quantity of electrical energy and to allow a reconciliation between the origin and/or the nature of this quantity of electrical energy and its consumption, typically in a register digital, dynamic, incorruptible and accessible to all.

Claims (10)

Method, implemented by an electrical outlet (2) connected to an electrical network (3), for certifying the consumption of a quantity of electrical energy supplied by the outlet (2) and consumed by an electrical device (4) connected to the socket (2), the electrical socket (2) being further connected, via a data communication network (10), to a distributed database (12) with a chain of blocks (24), each block of the chain of blocks (24) containing data representative of one or more electrical energy transactions, the electrical outlet (2) comprising memory means (14) and processing means (16) connected to the memory means (14) , the memory means (14) being configured to store said chain of blocks (24), the method comprising at least one step (30) of storing, by the memory means (14) of the electrical outlet (2), a current chain of blocks (24) originating from the distributed database (12), characterized in that the method further comprises the following steps:

• a supply (40), via the electrical outlet (2), of a predetermined quantity of electrical energy to said electrical device (4), said predetermined quantity of electrical energy being taken from the electrical network (3);
• an addition (42), by the processing means (16), of a new block to the current chain of blocks (24), thus forming a new chain of blocks, said new block containing data representative of a transaction of electrical energy, the transaction corresponding to said quantity of electrical energy taken from the electrical network (3) and supplied by the electrical outlet (2) to the electrical device (4);
• a transmission (44), via the electrical socket (2), of the new chain of blocks (24) to the distributed database (12), said transmission being carried out over the data communication network (10).

Method according to claim 1, characterized in that the method further comprises the following steps, carried out before the step (40) of supplying, through the electrical outlet (2), a predetermined quantity of electrical energy to said electrical appliance (4):

• storage (30), by the memory means (14), of an initial current chain of blocks (24) originating from the distributed database (12);
• reception (32), by the processing means (16), of a request (33) to consume said predetermined quantity of electrical energy, said request (33) corresponding to a request to consume said quantity of energy electricity by the electrical appliance (4) connected to the socket (2), said request (33) comprising an electronically signed electrical energy transaction;
• validation (34), by the processing means (16), of the electronic signature of said electrical energy transaction;
• an addition (36), by the processing means (16), of a new block to the initial current chain of blocks (24), thus forming a new chain of blocks, said new block containing data representative of said transaction d 'electric energy ;
• a transmission (38), via the electrical outlet (2), of the new chain of blocks (24) to the distributed database (12), said transmission being carried out over the data communication network (10).

Method according to claim 1 or 2, characterized in that, during the step(s) (36, 42) of adding a new block to the current chain of blocks (24), the processing means ( 16) of the electrical outlet (2) also add in the new block a checksum of the electrical energy transaction(s) of which said block is representative. Method according to any one of the preceding claims, characterized in that, during the step(s) (36, 42) of adding a new block to the current chain of blocks (24), the said data representative the electrical energy transaction(s) further contain an electronic signature representative of the socket (2). Method according to any one of the preceding claims, characterized in that a public address is associated with the electrical outlet (2) in the distributed database (12) with block chain (24), and in that the means memory (14) of the electrical outlet (2) are configured to store a private encryption key associated with the outlet, said private encryption key being configured to cooperate with said public address to allow manipulation of said public address by a user of the electrical socket (2). Method according to any one of the preceding claims, characterized in that the data communication network (10) is a private blockchain network conforming to the Ethereum protocol, and in that the distributed blockchain database (12) of blocks (24) complies with the Ethereum protocol. A method as claimed in any preceding claim, characterized in that the distributed blockchain (24) database (12) conforms to the distributed ledger protocol DLT. Electrical outlet (2) intended to be connected on the one hand to an electrical network (3), and on the other hand to a distributed database (12) with block chain (24) via a data communication network ( 10), the electrical outlet (2) comprising memory means (14) and processing means (16) connected to the memory means (14), the memory means (14) being configured to store said chain of blocks (24), characterized in that the electrical outlet (2) is configured to implement the method for certifying the consumption of a quantity of electrical energy according to any one of the preceding claims. Electrical socket (2) according to Claim 8, characterized in that the processing means (16) and the memory means (14) of the electrical socket (2) are in the form of a crypto-authentication chip (18 ), said crypto-authentication chip (18) storing a private encryption key associated with the outlet (2), said private encryption key being configured to cooperate with a public address associated with the electrical outlet (2) in the database distributed data (12) to a chain of blocks (24), to allow manipulation of said public address by a user of the electrical outlet (2). Electrical outlet (2) according to Claim 9, characterized in that the crypto-authentication chip (18) is a single-board nanocomputer with an ARM processor.