EP3959791A1

EP3959791A1 - System and method for distributing electrical power

Info

Publication number: EP3959791A1
Application number: EP20719653.6A
Authority: EP
Inventors: François BIRLING; Jean-François AFFOLTER; Georges BERWEILER
Original assignee: Homsphere SA
Current assignee: Homsphere SA
Priority date: 2019-04-25
Filing date: 2020-04-24
Publication date: 2022-03-02
Also published as: US20220200284A1; US11646582B2; EP3731363A1; CA3137776A1; WO2020216881A1

Abstract

The invention relates to a system for managing the distribution of electrical power between at least two distinct buildings each comprising a domestic network connected to a local network, said local network being connected to a public network. Each building comprises a power source, an inverter connected to said power source, a battery supplied with power by the inverter, and at least one apparatus operating using the power from the domestic network. The system comprises, in each building, a domestic module for regulating the power flow through the domestic network. The system further comprises a central module connected to each domestic module making it possible to regulate the power flow between the local network and the public network, said central module being arranged so as to regulate the power flow between the buildings in order to allow an exchange of power between a domestic network in excess and a domestic network in deficit.

Description

Electric power distribution system and method

TECHNICAL FIELD OF THE INVENTION

[001] The invention relates to an electrical energy distribution system as well as a method using the system according to the invention. The invention also relates to a computer implemented method and a computer program.

STATE OF THE ART

[002] Smart grids or intelligent networks (also called microgrid) are energy distribution systems that aim to optimize energy consumption between several buildings. For this, part of the energy needs are supplied by a local energy source.

[003] Smart grids have in particular been developed to overcome the difficulties of supplying energy to certain regions of the world. Even today, 17% of the world's population lives without access to electricity. Thanks to smart grids, solutions can be implemented for the electrification of these regions.

[004] A smart grid is commonly made up of a renewable energy generator, an energy generator using fossil fuel, energy storage means, and a local distribution network. The homes, generators and the storage solution are connected to the local network.

[005] The energy supplied to homes is preferably energy from the generator using renewable energy, for example solar panels. If this supply is not sufficient to cover the energy needs, the generator using fossil fuels can avoid power cuts.

[006] However, one of the drawbacks of existing microgrids is that the energy sources and the storage means are shared. In other words, the existing microgrids do not take into account the consumption habits of each dwelling to optimize distribution and minimize the use of fossil and / or nuclear energy

OBJECT OF THE INVENTION

[007] An object of the present invention is therefore to solve the problems described above, and more particularly to provide a distribution system and method. energy to optimize the management of the energy generated by the energy source of each building to avoid losses.

[008] Another object of the present invention is to provide a system which minimizes the consumption of electrical energy from the public grid.

[009] These objects are at least partially achieved by the present invention.

[010] The present invention relates to an electrical energy distribution system between buildings to manage the distribution of electrical energy between at least two separate buildings,

- the system comprising a home network in each building, each home network being connected to a local network, said local network being connected to a public network,

- the system comprising in each building o a domestic energy source to supply the domestic network, o an inverter connected to said energy source to convert the DC current generated by said energy source into AC current, o a battery for store domestic energy and distribute it in the home network, the battery being powered by the inverter, and at least one item of equipment operating using energy from the home network, the system comprising on the one hand a home module in each building and on the other hand a central module connected to each domestic module,

said domestic module making it possible to regulate the flow of energy circulating in the domestic network between the source, the inverter, the battery and said equipment as a function of the ratio defined by the available energy Ed and the energy consumed Ec on said network domestic, said domestic module being configured to calculate said ratio and transmit said ratio to the central module,

said central module being arranged to regulate the flow of energy between the buildings as a function of the Ed / Ec ratios transmitted by each domestic module so as to allow an exchange of energy between an excess domestic network and a deficient domestic network. [01 1] In the present invention, each domestic module regulates the energy flow of a domestic network. For example, the domestic module distributes the available energy to network equipment. The domestic module calculates the Ed / Ec ratio and transmits this information to the central module.

[012] The buildings, more precisely the home networks of the buildings, are connected to a local network. The local network is linked to a public network.

[013] The central module manages the energy supply to each home network. For example, the central module controls the energy source and the battery of each building. If a domestic module communicates an energy deficit to the central module, the central module carries out the necessary actions to overcome this deficit. For example, an energy deficit is defined by an Ed / Ec ratio less than zero. In other words, the central module uses the information provided by the home modules to regulate the flow of energy between the local network and the home networks.

[014] The central module regulates the flow of energy between the home networks. If a network has an energy deficit and another domestic network is on the contrary in excess, the central module allows a transfer between the excess domestic network and the deficit domestic network.

[015] The central module controls the transfer of excess energy to the deficit network. Energy transfer can take place between home networks. The transfer can take place between batteries, that is, between the battery of a home network with excess energy and the battery of the home network with a deficit.

[016] Alternatively, the transfer can take place between the battery of an excess network and equipment connected to a deficient home network.

[017] Alternatively, the transfer can take place between the power source of an excess grid and the battery of a deficit grid.

[018] In the present invention, there are 3 levels of networks: the home network, the local network and the public network. The buildings of the same local network are connected and can pool the available energy produced by each of the buildings. If one of the buildings (or buildings) of the local network has an energy deficit, the other buildings of the local network can fill this deficit thanks to the local network without having to resort to energy from the public network. If at least one of the buildings is in excess, the deficit can be made up without using energy from the public grid.

[019] In other words, the present invention makes it possible to use the energy available in the local network to meet the needs of the domestic networks connected to the network. local. Advantageously, this makes it possible to obtain a self-sufficient energy system, in particular a self-sufficient system thanks to the optimization of the self-consumption of the energy produced in the local network. This characteristic is not described in the energy distribution or microgrid systems known from the prior art. In addition, this makes it possible to compensate for power cuts in the event of a power failure in the public network.

[020] When energy transfers between buildings in the same local network are free of charge, it allows users of each building to save the energy costs corresponding to the purchase of energy from the public network.

[021] In one embodiment, said central module makes it possible to regulate the flow of energy between the local network and the public network, so that, when the local network has an energy deficit, said central module allows an input of energy from the public grid to the local grid.

[022] According to one embodiment, said central module makes it possible to regulate the flow of energy between the local network and the public network, so that, when the local network is in excess of energy, said central module allows an output energy from the local network to the public network.

[023] When the local network does not make it possible to meet the needs of one or more domestic networks, the central module activates the transfer of energy between the public network and the local network then controls the domestic module concerned to introduce the energy in the home network in deficit. Conversely, when the local network is in excess of energy, the control module can order a transfer of energy from the local network to the public network. This solves the problems of storing energy produced by energy sources in buildings in home networks. The present invention therefore makes it possible to produce energy.

[024] In one embodiment, the household energy source is a renewable energy source, for example selected from solar, wind, geothermal, biomass, preferably photovoltaic panels.

[025] According to one embodiment, said batteries are chosen from lithium batteries, lead batteries, preferably lithium batteries.

[026] In one embodiment, which said equipment item is chosen from a list comprising a heat pump, an electric vehicle, a light, a blind, a ventilation system, a heating and / or cooling system, multimedia equipment television or computer type, an alarm type security device, or a combination of these devices. [027] Advantageously, the equipment is connected to controlled outlets. For example, the devices are interconnected via a communication bus or via electrical outlets.

[028] Advantageously, the present invention comprises a heat pump of smartgrid ready type, in other words a heat pump controllable by a central module which controls its operation, in particular the operating time slot.

[029] In one embodiment, said batteries have capacities of between 10 and 100 kWh.

[030] According to one embodiment, said buildings are chosen from individual houses, buildings comprising several dwellings.

[031] In the present invention, the constituent elements of the system communicate with each other using one or more protocols.

[032] For example, each domestic module uses a home automation protocol, for example KNX, for communication between the devices. Advantageously, the present invention uses a particular protocol to ensure communication between technical equipment such as for example ventilation, heating, water or energy meter, for example a ModBUS protocol.

[033] Advantageously, the protocols are all integrated into the domestic module which controls the equipment. Thus, information relating to equipment, in particular their energy requirements, is centralized at the level of the domestic module. The home module communicates this information to the central module which regulates the flow of energy in the local network between buildings based on said information.

[034] The present invention also relates to a method of distributing electrical energy between buildings to manage the distribution of electrical energy between at least two separate buildings, the method comprising:

- i) providing a system according to the present invention;

- ii) configure the domestic module of each building so as to calculate the ratio between the available energy Ed and the consumed energy Ec on each domestic network;

- iii) provide the central module with the Ed / Ec ratio of each domestic module;

- iv) configure the central module according to the Ed / Ec ratios of each domestic module to allow regulation of energy flows between the network of each building and the local network, so that, for each building, o iv) a) when Ed is greater than Ec, the central module activates the domestic module of the building to allow an exit of the excess energy from the home network from said building to the local network; or o iv) b) when Ed is equal to Ec, the central module controls the domestic module of the building to block the flow of energy between the domestic network of said building and the local network; or iv) c) when Ed is less than Ec, the central module activates the building's domestic management module to allow energy input from the local network to the domestic network of said energy-deficient building;

[035] The advantages of the method according to the present invention are similar to those of the system and therefore will not be repeated here.

[036] According to one embodiment, the excess energy from a home network is used to charge the battery of a home network in deficit or to power a home network in deficit.

[037] In one embodiment, excess energy from a home network is fed into the local network and then into the public network.

[038] According to one embodiment, the central module is configured to activate the input of electrical energy into at least one of the domestic networks in deficit over a predetermined time slot.

[039] In one embodiment, the central module is configured to compensate for a deficient home network, for example charging a deficient battery, as a function of:

- meteorological parameters; and or

- excess energy available in another home network;

[040] According to one embodiment, when a home network is in deficit, the central module is configured to prioritize use of excess energy from another home network. If the energy available on the local network is not available in sufficient quantity to compensate for the deficit, the central module uses the public network to supplement the energy supply. [041] The invention also relates to a computer-implemented method, in which the method uses a computer program to execute the steps of the method according to the invention.

[042] The invention also relates to a computer program comprising instructions which, when the program is executed by a computer, make it possible to control a system according to the invention. Preferably, said program is arranged to control the central module so as to regulate the flow of energy between buildings and allow an exchange of energy between an excess home network and a deficit home network.

[043] The computer program can be stored in the central module. Alternatively, the program can be stored on a server or cloud.

[044] In the present invention, the terms "home module" define a module for managing the electrical energy of the home network. For example, the household module can be composed of a smart electricity meter and equipment (s) for communication with the renewable energy production and storage system.

[045] In the present invention, the terms "central module" define a module for managing the electrical energy of the local network. For example, the domestic module can be an EMS for Energy Management System. For example, the central module can be an EMS consisting of a PLC / computer, one or more communication modules and a smart electricity meter.

[046] The embodiments described for the system according to the present invention also apply to the method according to the invention, to the computer-implemented method and to the computer program, mutatis mutandis.

BRIEF DESCRIPTION OF THE FIGURES

[047] Other advantages, aims and particular characteristics of the invention will emerge from the non-limiting description which follows of at least one particular embodiment of the device and of the method which are the subject of the present invention, with reference to the accompanying drawings, wherein

- Figure 1 shows three scenarios for a building;

- Figure 2 shows three scenarios at the level of a set of buildings;

DESCRIPTION OF EXAMPLES OF EMBODIMENT OF THE INVENTION [048] The present description is given without limitation, each characteristic of an embodiment being able to be combined with any other characteristic of any other embodiment in an advantageous manner. We can now note that the figures are not to scale.

[049] Figures 1 a, b, c represent three possible situations for each building 2a, b, c of a system 1 a, b, c according to the invention. Figures 1 a, b, c each represent a building 2a, b, c of a system, the system not being fully illustrated in Figure 1.

[050] The building 2a, b, c comprises a home network 3a, b, c connected to a local network 4a, b, c, said local network 4a, b, c being connected to a public network 5a, b, c.

[051] Each building 2a, b, c includes photovoltaic panels 7a, b, c as an energy source to supply the domestic network 3a, b, c.

[052] The home network 3a, b, c includes a lithium battery 7a, b, c connected to an inverter 8 a, b, c to supply electrical energy to the home network 3a, b, c.

[053] The energy from the domestic network 3a, b, c is used to supply equipment 9a, b, c, for example a heat pump 10a, b, c.

[054] Each building 2a, b, c further comprises a domestic module 1 1 a, b, c to regulate the flow of energy circulating in the domestic network 3a, b, c. Each domestic module is connected to a central module 12 a, b, c which controls the supply of electrical energy to the domestic network 3a, b, c.

[055] In Figures 1 a, b, c, the arrows indicate a flow of energy, each arrow being accompanied by a number indicating the intensity of the flow.

[056] In Figure 1a, the building 2a is in an ideal case of self-sufficiency because there is no energy exchange necessary between the home network 3a and the local network 4a. The available energy Ed of the solar panels 6a and in the battery 7a corresponds to the energy consumed Ec of the equipment of the building 2a. The sum of the intensities produced (3 + 2 = 5) corresponds to the intensities required for the equipment 9a and 10a (respectively 4 and 1), the Ed / Ec ratio is zero.

[057] In the case shown in Figure 1a, the central module 12a blocks the flow of energy between the home network 3a and the local network 4a.

[058] In Figure 1b, the available energy Ed is greater than the consumed energy Ec, the ratio Ed / Ec = 2. The domestic network 3b is thus surplus. The central module 12b allows an exit of the excess energy from the domestic network 3b to the local network 3c. This excess energy can be used to compensate a network domestic loss of the local network. If all of the domestic networks are self-sufficient or also in excess, the central module 12b can make it possible to introduce excess energy into the public network 5b.

[059] In figure 1c, the available energy Ed is less than the consumed energy Ec, the ratio Ed / Ec = -5. The domestic network 3c is thus in deficit. The central module 12c allows an entry of energy from the local network 4c. This energy introduced into the home network 3c can come from a home network in excess of the local network. If all the domestic networks are self-sufficient or also in deficit, the central module 12c introduces energy from the public network 5c into the local network 4c and then into the domestic network 3c to meet the energy needs of the domestic network 3c.

[060] Figures 2a, b, c represent three possible situations for a system 100a, b, c according to the invention.

[061] Each system 100a, b, c comprises three buildings 102a, b, c whose home networks (not shown in Figures 2a, b, c) are connected to a local network 104a, b, c, said local network 104a , b, c being connected to a public network 105a, b, c. Each system 100a, b, c also comprises a central module 1 12a, b, c.

[062] As for Figures 1 a, b, c, the arrows indicate a flow of energy, each arrow being accompanied by a number indicating the intensity of the flow.

[063] In the case represented in FIG. 2a, the system 100a is self-sufficient, in other words each building 102a has a zero Ed / Ec ratio. The needs of the system 100a are met only by the energy available on the local network 104a.

[064] In the case shown in FIG. 2b, the local network 104b of the system 100b has an excess balance of +2 (7-5 = 2) which can be introduced into the public network 105b since none of the buildings 102b is in energy deficit. In this embodiment, the energy deficit of one building is filled by the excess energy of another building.

[065] In the case shown in Figure 2c, the situation is the opposite of that shown in Figure 2b. The local network 104c of the system 100c has a deficit balance of -1 (-3-5 + 7-1). The central module 1 12c thus allows an energy input from the public network 105c to fill the energy deficit of the system 100c. In this embodiment, the local network 104c does not have sufficient energy resources to cover the needs of the local network 104c, that is to say of the home networks connected to the local network 104c. In this case, the 100c system is configured to allow an energy input from the public network 105c to avoid the power cut.

[066] To illustrate the present invention, in an exemplary embodiment, the local network comprises 6 buildings, the buildings being residential villas. In a study over a period of 11 months (in other words over a period covering the 4 seasons), the applicant observed the following data:

- Energy production of 6 buildings: 47,578 kWh according to the following distribution:

15,665 kWh in self-consumption for all buildings, in other words on domestic networks; 7Ό60 kWh distributed on the local network; 24,853 kWh distributed on the public network;

- Energy consumption of the 6 buildings: 35,239 kWh according to the following breakdown: 15,665 kWh in self-consumption for the buildings in all the domestic networks; 7Ό60 kWh from the local network; 12,514 kWh from the public network;

[067] As illustrated by the data of this example, in the present invention the buildings are self-sufficient in energy between themselves for 64% (44 + 20) of their energy needs.

[068] The last third of the energy requirement is supplied by the public network. This exchange is financially neutral because the buildings sell more energy (24,853 kWh or CHF 2,784) than they buy (12,514 kWh or CHF 2,366 - the price per kWh purchased being higher than the price per kWh sold).

[069] In conclusion, the 6 buildings of the local network are both mainly energy and financially self-sufficient.

[070] The 6 buildings produced 35% solar energy below their needs, this excess being made available to the public network.

[071] Advantageously, each building is equipped with a device, for example a computer, a tablet or a smartphone. A program, for example software, is installed on the device, the program making it possible to monitor the consumption of the house in real time on the three networks, namely the home network, the local network and the public network.

[072] In particular, the program can make it possible to know in real time the origin of the energy consumed by the building (that is to say by the building equipment): energy from the domestic network, from the network local or public network. [073] The program can also provide information on the energy flows between the various buildings on the local network. The program can also make it possible to know the energy flows between the local network and the public network.

[074] The program installed on each device is preferably connected to the central module, in particular to the program which controls the central module. This allows the user of the device to have real-time access to system data, for example the origin of energy, energy flows, the energy ratio of buildings connected to the local network.

[075] The central module program preferably records the consumption and production data of each building in the local network. This makes it possible, for example, to define or adjust energy strategies based on the data collected, for example for the source of energy to be used to meet the needs of a building at a given time.

he REFERENCE NUMBER a, b, c System according to the invention

a, b, c Building of a system according to the invention

a, b, c Home network

a, b, c Local network

a, b, c Public network

a, b, c Photovoltaic panels

a, b, c Lithium battery

a, b, c Inverter

a, b, c Equipment

0 a, b, c Heat pump

1 a, b, c Domestic module

2 a, b, c Central module 00a, b, c System according to the invention

02a, b, c Building of a system according to the invention

04a, b, c Local network

05a, b, c Public network

12 a, b, c Central module

Claims

1. Electrical energy distribution system (1 a, b, c; 100a, b, c) between buildings to manage the distribution of electrical energy between at least two buildings (2a, b, c; 102a, b, c ) distinct,

- the system (1 a, b, c; 100a, b, c) comprising a home network (3a, b, c; 103a, b, c) in each building (2a, b, c; 102a, b, c) , each home network (3a, b, c; 103a, b, c) being connected to a local network (4a, b, c; 104a, b, c), said local network (4a, b, c; 104a, b , c) being connected to a public network (5a, b, c; 105a, b, c),

- the system (1 a, b, c; 100a, b, c) comprising in each building (2a, b, c; 102a, b, c)

• a domestic energy source (6a, b, c) to supply the domestic network (3a, b, c; 103a, b, c),

• an inverter (8a, b, c) connected to said energy source (6a, b, c) to convert the DC current generated by said energy source (6a, b, c) into AC current,

• a battery (7a, b, c) for storing domestic energy and distributing it in the domestic network (3a, b, c; 103a, b, c), the battery (7a, b, c) being powered by the 'inverter (8a, b, c), and

• at least one device (9a, b, c) operating using energy from the home network (3a, b, c; 103a, b, c), the system (1 a, b, c; 100a, b, c ) comprising on the one hand a domestic module (1 1 a, b, c) in each building (2a, b, c; 102a, b, c) and on the other hand a central module (12a, b, c; 1 12a, b, c) connected to each domestic module (1 1 a, b, c),

- Said domestic module (1 1 a, b, c) for regulating the flow of energy circulating in the domestic network (3a, b, c; 103a, b, c) between the source (6a, b, c), the inverter (8a, b, c), the battery (7a, b, c) and said equipment (9a, b, c) according to the ratio defined by the available energy Ed and the consumed energy Ec on said network domestic (3a, b, c; 103a, b, c), said domestic module (1 1 a, b, c) being configured to calculate said ratio and transmit said ratio to the central module (12a, b, c; 112a, b ,vs),

- said central module (12a, b, c; 1 12a, b, c) being arranged to regulate the flow of energy between the buildings (2a, b, c; 102a, b, c) according to the Ed / Ec ratios transmitted by each domestic module (1 1 a, b, c) so as to allow an exchange of energy between a home network (3a, b, c; 103a, b, c) in excess and a home network (3a, b, c; 103a, b, c) in deficit.

2. System (1 a, b, c; 100a, b, c) according to claim 1, wherein said central module (12a, b, c; 1 12a, b, c) makes it possible to regulate the flow of energy between the local network (4a, b, c; 104a, b, c) and the public network (5a, b, c; 105a, b, c), so that when the local network (4a, b, c; 104a , b, c) is energy deficient, said central module (12a, b, c; 1 12a, b, c) allows energy input from the public network (5a, b, c; 105a, b, c) to the local network (4a, b, c; 104a, b, c).

3. System (1 a, b, c; 100a, b, c) according to one of claims 1 or 2, wherein said central module (12a, b, c; 1 12a, b, c) makes it possible to regulate the energy flow between the local network (4a, b, c; 104a, b, c) and the public network (5a, b, c; 105a, b, c), so that when the local network (4a, b, c; 104a, b, c) is in excess of energy, said central module (12a, b, c; 1 12a, b, c) allows an energy output from the local network (4a, b, c; 104a, b, c) to public network (5a, b, c; 105a, b, c).

4. System (1 a, b, c; 100a, b, c) according to one of claims 1 to 3, wherein the energy source (6a, b, c) is a renewable energy source, by example chosen from solar, wind, geothermal, biomass, preferably photovoltaic panels.

5. System (1 a, b, c; 100a, b, c) according to one of claims 1 to 4, wherein said batteries (7a, b, c) are chosen from lithium batteries, lead batteries , preferably lithium batteries.

6. System (1 a, b, c; 100a, b, c) according to one of claims 1 to 5, wherein said equipment (9a, b, c) is chosen from a list comprising a heat pump (10a , b, c), an electric vehicle, a light, a blind, a ventilation system, a heating and / or cooling system, multimedia equipment such as television or computer, a security device such as an alarm, or a combination of this equipment.

7. Method of distribution of electrical energy between buildings to manage the distribution of electrical energy between at least two separate buildings (2a, b, c; 102a, b, c), the method comprising:

- i) providing a system (1 a, b, c; 100a, b, c) according to one of claims 1 to 6;

- ii) configure the domestic module (1 1 a, b, c) of each building (2a, b, c; 102a, b, c) so as to calculate the ratio between the available energy Ed and the consumed energy Ec on each home network (3a, b, c; 103a, b, c); - iii) provide the central module (12a, b, c; 1 12a, b, c) with the Ed / Ec ratio of each domestic module (1 1 a, b, c);

- iv) configure the central module (12a, b, c; 1 12a, b, c) according to the Ed / Ec ratios of each domestic module (1 1 a, b, c) to allow regulation of energy flows between the home network (3a, b, c; 103a, b, c) of each building (2a, b, c; 102a, b, c) and the local network (4a, b, c; 104a, b, c) , so that, for each building (2a, b, c; 102a, b, c),

- a) when Ed is greater than Ec, the central module (12a, b, c; 1 12a, b, c) allows excess energy to be released from the domestic network (3a, b, c; 103a, b, c) from said building (2a, b, c; 102a, b, c) to the local network (4a, b, c; 104a, b, c); or

- b) when Ed is equal to Ec, the central module blocks the flow of energy between the domestic network (3a, b, c; 103a, b, c) of said building (2a, b, c; 102a, b, c ) and the local network (4a, b, c; 104a, b, c); or

- c) when Ed is less than Ec, the central module (12a, b, c; 1 12a, b, c) allows energy input from the local network (4a, b, c; 104a, b, c) to the domestic network (3a, b, c; 103a, b, c) of said building (2a, b, c; 102a, b, c) deficient in energy;

8. Method according to claim 7, wherein the excess energy of a home network (3a, b, c; 103a, b, c) is used to charge the battery of a home network (3a, b, c; 103a, b, c) in deficit or to supply a home network in deficit.

9. The method of claim 7 or 8, wherein the excess energy from a domestic network (3a, b, c; 103a, b, c) is introduced into the local network (4a, b, c; 104a , b, c) then in the public network (5a, b, c; 105a, b, c).

10. Method according to one of claims 7 to 9, wherein the energy deficit of a domestic network (3a, b, c; 103a, b, c) is filled at least in part by an energy input. from the public network (5a, b, c; 105a, b, c).

1 1. Method according to one of claims 7 to 10, in which the central module (12a, b, c; 1 12a, b, c) is configured to activate the input of electrical energy into at least one of the domestic networks (3a , b, c; 103a, b, c) in deficit over a predetermined time slot.

12. Method according to one of claims 7 to 1 1, wherein the central module (12a, b, c; 1 12a, b, c) is configured to compensate for a home network (3a, b, c; 103a, b , c) deficit depending on:

- meteorological parameters; and or

- excess energy available in another home network (3a, b, c; 103a, b, c);

13. Method according to one of claims 7 to 12, wherein, when a home network (3a, b, c; 103a, b, c) is in deficit, the central module (12a, b, c; 1 12a, b, c) is configured to prioritize use of excess energy from another home network (3a, b, c; 103a, b, c).

14. A computer-implemented method, wherein the method uses a computer program to perform the steps of the method according to one of claims 7 to 13.

15. Computer program comprising the instructions which, when the program is executed by a computer, make it possible to control a system (1 a, b, c; 100a, b, c) according to one of claims 1 to 6, said schedule being arranged for

control the central module (12a, b, c; 1 12a, b, c) so as to regulate the flow of energy between the buildings (2a, b, c; 102a, b, c) and allow energy exchange between a home network (3a, b, c; 103a, b, c) in excess and a home network (3a, b, c; 103a, b, c) in deficit.