WO2014049269A1 - Method for determining a forecast of the electric power supplied by a facility for supplying electric power - Google Patents

Abstract

The invention relates to a method for determining the electrical power supplied by a facility (10) including a power storage system (14) and an electric power plant (12). The method includes determining, in accordance with weather forecasts for a first time interval, the predicted variation of the power produced by the electric power plant during the first time interval; determining, in accordance with the predicted variation, at least one power level and at least one second time interval, contained in the first time interval, during which the electric power plant is capable of supplying the power at said level; and modifying the initial terminal and/or the final terminal of the second time interval in accordance with the desired variation of the state of charge of the storage system, determined in accordance with a model of the storage system, during the first time interval.

Description

 METHOD FOR DETERMINING A FORECAST OF ELECTRICAL POWER SUPPLIED BY AN ENERGY SUPPLY FACILITY

 ELECTRIC

Field of the invention

 The present invention relates to a method for determining a forecast of the electric power supplied during a time interval by an energy supply installation comprising an energy storage system and a power plant using a renewable energy source, These include solar energy, wind energy, wave energy, stream energy, marine energy and / or tidal energy.

Presentation of the prior art

The electricity supply to elec ^¬ tric network by electricity supply system must generally meet the constraints imposed by the manager of the power grid. In particular, one of these constraints is that the manager of the energy supply facility transmits in advance to the power grid manager a power generation plan in which he undertakes to supply electrical power. given for at least a given time interval. The power supplied by a power plant using a renewable energy source, in particular those mentioned above, is variable and depends on the meteorological conditions. The power plant alone is therefore not able to transmit in advance a power plan.

 There is therefore a need for a method for determining the electrical power supplied by an energy supply installation comprising an energy storage system and a power plant using a renewable energy source, in particular those mentioned above. high .

summary

 An object of an embodiment of the invention is to overcome all or part of the disadvantages of the known methods for determining the electrical power supplied by an energy supply installation comprising an energy storage system and a power plant. using a renewable energy source.

 Another object of an embodiment of the present invention is that the installation provides electrical power at a constant level for at least one time interval.

 Another object of an embodiment of the present invention is that the difference between the actual electrical power supplied by the plant and the prediction is less than a threshold.

 Another object of an embodiment of the present invention is that the state of charge of the energy storage system at the end of the time interval corresponds to a desired state of charge.

Another object of an embodiment of the present invention is that the method of determining the electrical power supplied by a power supply installation can be implemented by a simple program making operate a processor or can be implemented by a dedicated electronic circuit of simple design.

 Thus, an embodiment of the present invention provides a method, implemented by a processor or by an electronic circuit, for determining the electrical power supplied by an electrical energy supply installation comprising a system for storing energy. and a power plant, the method comprising:

 determining, based on weather forecasts over a first time interval, the expected evolution of the electric power produced by the power station during the first time interval;

 determining, from the expected evolution, at least one electrical power level and at least one second time interval, contained in the first time interval, during which the power plant is capable of supplying the power electrical audit level; and

 modifying the initial terminal and / or the final terminal of the second time interval according to the desired evolution of the state of charge of the energy storage system, determined from a model of the storage system of energy, during the first time interval.

 According to an embodiment of the present invention, the method comprises the following successive steps:

 receive weather forecasts on the first time interval;

 determine the expected evolution of the electric power produced by the power station during the first time interval from the weather forecasts;

 determine the level of electrical power from the expected evolution; and

determine the second time interval from the expected evolution and the electric power level. According to an embodiment of the present invention, the method further comprises the following step:

 decreasing the initial bound if the state of charge of the energy storage system is greater than or equal to a first threshold for at least one time of the second time interval other than the final terminal.

 According to an embodiment of the present invention, the method further comprises the following step:

 increasing the initial limit if the state of charge of the energy storage system is strictly less than or equal to a second threshold during the second time interval.

 According to an embodiment of the present invention, the method further comprises the following step:

 modify the final terminal as long as the state of charge of the energy storage system at the final terminal is different from a third threshold.

 According to an embodiment of the present invention, the step of modifying the final terminal comprises the following steps:

 increase the final terminal as long as the state of charge of the energy storage system at the final terminal is strictly greater than the third threshold.

 According to an embodiment of the present invention, the step of modifying the final terminal comprises the following steps:

 decrease the final terminal as long as the state of charge of the energy storage system at the final terminal is strictly less than the third threshold.

 According to one embodiment of the present invention, the step of modifying the final terminal is performed after the step of modifying the initial terminal.

According to one embodiment of the present invention, the electric power level is strictly less than or equal to the maximum of the expected evolution of the electric power and the second time interval corresponds to the interval of time during which the expected electrical power exceeds said level.

 Another embodiment of the present invention provides a method of power supply by an electrical power supply installation comprising an energy storage system and a power plant comprising the following steps:

 determination of the electric power supplied by the electrical energy supply installation as defined above; and

 supply of electrical power at the electrical power level, with an error range of less than 5%, during the second time interval.

 Another embodiment of the present invention provides a computer support for storing a computer program for implementing the method as defined above.

 Another embodiment of the present invention provides an electrical energy supply installation comprising an energy storage system and a power plant, the installation comprising at least one processor programmed for or an electronic circuit adapted to:

 determining, based on weather forecasts over a first time interval, the expected evolution of the electric power produced by the power station during the first time interval;

 determining, from the expected evolution, at least one electrical power level and at least a second time interval, contained in the first time interval, during which the power plant is capable of supplying the electrical power at said level; and

modifying the initial terminal and / or the final terminal of the second time interval according to the desired evolution of the state of charge of the energy storage system, determined from a model of the energy storage system, during the first time interval.

 According to one embodiment of the present invention, the power plant can be a power station using solar energy, wind energy, wave energy, watercourse energy, marine current energy and / or the energy of the tides.

 According to one embodiment of the present invention, the energy storage system comprises a system selected from the group consisting of electric batteries, a flywheel system, a compressed air system, a transfer station of energy pumped and a fuel cell system and electrolyzer.

Brief description of the drawings

 These and other objects, features, and advantages will be set forth in detail in the following description of particular embodiments in a non-limitative manner with reference to the accompanying figures in which:

 FIG. 1 represents, partially and schematically, an embodiment of an electrical energy supply installation according to the invention;

 FIG. 2 represents, in the form of a schematic block, an embodiment according to the invention of a method for determining the electrical power supplied by the installation of FIG. 1;

 Fig. 3 is a timing chart of signals illustrating the embodiment of the method for determining the electrical power of Fig. 2;

 Figures 4 to 6 show, in the form of block diagrams, more detailed embodiments of steps of the embodiment of the method of Figure 2; and

FIGS. 7 and 8 are timing diagrams of signals during the implementation of the embodiment of the method of FIG. 2 for two examples of initial state of charge of the energy storage system. For the sake of clarity, the same elements have been designated with the same references in the various figures.

detailed description

 In the remainder of the description, only the elements necessary for understanding the invention are described in detail. Thus, the structure of an electrical network to which is connected a power supply installation is known and is not described in detail.

 FIG. 1 represents an embodiment of an installation 10 for supplying electrical energy according to the invention. The installation 10 comprises a power plant 12 (ENR) and an energy storage system 14 (Storage).

 The power plant 12 is an electric power generation system using a renewable energy source. For example, the power plant 12 may be a power plant using solar energy, wind energy, wave energy, watercourse energy, marine energy and / or energy. tidal energy. For example, the power plant 12 can provide a voltage or a DC or AC current. In the case where the power plant 12 corresponds to a solar power plant, it can provide a voltage or a direct current.

 The energy storage system 14 is a system that can store electrical energy, possibly by transforming it into another form, and restore all or part of the stored electrical energy. The energy storage system 14 may be a system selected from the group consisting of electric batteries, a flywheel system, a compressed air system, a pumped energy transfer station or a battery operated system. fuel and electrolyzer. By way of example, the energy storage system 14 provides a voltage or a direct current and is charged by a voltage or a direct current.

The state of charge SOC of the energy storage system 14 is the ratio of the total amount of energy capable of being stored in the energy storage system 14, and which may depend on the operating conditions of the storage system, and the amount of energy actually stored in the energy storage system 14.

 The installation 10 includes an interface system 16

(Plant Control System) which connects the power plant 12 to the energy storage system 14 and in particular allows the charging of the energy storage system 14 from the electrical energy supplied by the power plant 12.

 The installation 10 is connected to an electrical network 18

(Network) which transports electrical energy from the installation 10 to electrical energy consumption systems 20 (Consumer), only one of these systems being shown in FIG. electrical energy can be connected to the electrical network 18.

Depending on the type of power grid 18 and instal lation ^¬ 10, the plant 10 may provide a voltage or an AC or DC network 18. In the case where facility 10 provides a voltage or an alternating current and power plant 12 and / or the energy storage system 14 provide a voltage or a DC current, the interface system 16 may comprise a DC-AC converter for converting the voltage or DC current supplied by the power station 12 and / or the energy storage system 14 in a voltage or an alternating current supplied to the network 18. As a variant, at least some elements of the interface system 16 may be part of the power plant 12 or the control system. energy storage 14.

In the case where the electricity network 18 carries a voltage or an alternating current and that the energy storage system 14 is charged by a voltage or a direct current, the interface system 16 may, in addition, comprise an alternating converter. -continued allowing the system load energy storage 14 from the electricity provided by the electricity network 18.

 In the present embodiment according to the invention, the installation 10 further comprises an energy management module 22 (Energy Management System). The module 22 is connected to the interface system 16, to the power station 12 and to the energy storage system 14. The module 22 comprises at least one dedicated electronic circuit for controlling the interface system 16, the power station 12 and / or the energy storage system 14 and / or at least one processor programmed to control the interface system 16, the power station 12 and / or the energy storage system 14. The dedicated electronic circuit and / or the processor can control at any moment:

 the electric power supplied by the power station 12;

 the electric power supplied by the energy storage system 14;

 the electric power supplied to charge the energy storage system 14; and or

 the electronic power supplied by the installation 10 to the electrical network 18.

 The energy management module 22 can furthermore receive data from the interface system 16, the power plant 12 and the energy storage system 14. For example, the storage system of energy 14 can transmit its state of charge to the energy management module 22.

The energy management module 22 may further receive data from a weather data system 24. The supply of data by the system 24 to the energy management module 22 can be done by any means, for example via the Internet. The data may include, in particular, weather forecasts over a time interval ΔΤ _] _. The energy management module 22 can determine the evolution of the power supplied by the power station 12 from the weather forecast and a model of operation of the power station 12.

If the power plant 12 is a solar power plant, weather forecasts include, for example, sunshine forecast for the inter ^¬ valle de ΔΤ _time] _ on where the power plant 12 is located. In the case where the power station 12 is a wind power station, the meteorological forecasts include, for example, forecasts of the speed and / or the orientation of the wind during the time interval ΔΤ _] _ at the places where the power station electrical 12 is implanted. In the case where the power station 12 is a power station using the wave energy, the energy of the streams, the energy of the marine currents and / or the energy of the tides, the meteorological forecasts include, for example, forecasts of the amplitude of the waves, river or marine currents, or tides during the time interval ΔΤ _] _ at the places where the power station 12 is located.

The energy management module 22 comprises at least one dedicated electronic circuit and / or or at least one processor programmed to determine a prediction of the electrical power supplied by the installation 10 during the future time interval ΔΤ _] _ and for provide, for example, this forecast to the manager of the electricity network 18. The determination of the electrical power supplied by the installation 10 is, for example, made from the day for the next day. For example, at the same time, each day, the energy management module 22 can transmit to the manager of the electrical network 18 the prediction of the electrical power supplied by the installation

10 for the next day.

FIG. 2 represents, in the form of a schematic block, an embodiment according to the invention of a method for determining in advance the electrical power supplied by the installation 10 as a function of time. In step 30, the energy management module 22 receives from weather forecasting system 24 meteorological data over the time interval ΔΤ] for which the determination of the electrical power supplied by the installation 10 must be carried out. . In addition, the management module 22 has the SOC-j_ _n -j_ state of charge of the energy storage system 14 at the instant when the determination of the electrical power is made. The energy management module 22 can store in a storage device, for example a memory, in particular a non-transient memory, the SOC-j_ _n -j_ state of charge and / or the meteorological data. The energy management module 22 determines a prediction of the expected electrical power provided by the power plant 12 during the future time interval ΔΤ] from the meteorological forecasts. The process continues in step 32.

 For example, the expected electrical power can be obtained from a physical law or from a statistical law. Examples of the law are described in the publication "Irradiance Forecasting for the Power Prediction of Grid-Connected Photovoltaic Systems" by E. Lorenz, J. Hurka, D. Heinemann, and HG Beyer (IEEE Journal of Selected Topics in Applied Earth Ob Remote Sensing, Vol 2, No. 1, March 2009) and the publication "How Much Will Energy Be Produced Tomorrow?" A Forecasting Tool that Fits the Future Electricity Market "from S.

Lespinats, F. Cugnet, H. Guillou, X. The Pivert (26th European Photovoltaic Solar Energy Conference, 2011).

FIG. 3 represents an example of an evolution curve of the electrical power • ENR provided on the interval ΔΤ] _ when the power station 12 is a solar power station. In a conventional manner, the evolution curve of the predicted electrical power PE R comprises successively, when the interval ΔΤ] _ starts from OhOO at 24h00, a zero power stage P] _, a growth phase P2, the passage through a maximum electric power PENRmax ^a phase Decreased numbers ^¬ health P3 and a zero power level P4.

In steps 32 to 36, the energy management module 22 determines a forecast, or production plan, of the electrical power supplied by the installation 10 to the electrical network 18 during the time interval ΔΤ _] _. The production plan may comprise a series of steps for each of which the electrical power supplied by the installation 10 is substantially constant, the bearings may have different durations.

Preferably, the production plane may comprise a single plateau at a constant electric power, hereinafter referred to as the reference electrical power P _re f _f during a time interval Δ 2, contained in the time interval ΔΤ _] _, which starts at a time t _] _ and ends at a time t2 · The supply of the production plan by the module 22 to the manager of the electrical network 18 includes the supply of the value of the reference electric power P _re f and times t and t2 ·

 According to one embodiment of the invention, at step

32, the management module 22 provides the power P _ref of the reference production plan that will be provided. The process continues in step 34.

In step 34, the management module 22 determines the start time t _] _ of the supply phase of the reference power P _re f by the installation 10. The method continues in step 36.

In step 36, the module determines the instant t2 corresponding to the end of the supply phase of the reference power P _re f by the installation 10.

The determination of the prediction of the electrical power supplied by the installation 10 during the time interval ΔΤ _] _ by the energy management module 22 is carried out respecting several constraints that may be imposed by the manager of the electrical network 18. Examples of constraints are the following:

in the case of a single bearing at the electric power P _re f, the duration during the time interval Δ 2 of supply of the electric power to the power P _re f is the longest possible;

during the electrical power level, the variations of the electrical power actually supplied by the installation 10 with respect to the reference power P _re f are less, in absolute value, than a given threshold, for example 2.5%;

- during the growth phase variation or decrease the power supplied by the plant 10 before and after bearing the reference power P _{ref f} eg between the zero level and the electric power reference P _ref, the rate of change per minute of the electric power is lower, in absolute value, at a given threshold, for example 0.6% of the total power, called P _max thereafter, which can be supplied by the power station 12 in the better operating conditions;

 during a phase of growth of the electrical power supplied by the installation 10, for example between the zero level and the electrical reference power Pref 'electric power supplied by the installation 10 must always be increasing or of zero variation;

during a phase of decay of the electrical power supplied by the installation 10, for example between the reference electric power P _re f ^e t the zero level, the electrical power supplied by the installation 10 must always be decreasing or zero variation;

- the reference power P _ref must be less than 40% of the maximum power P _max which can be supplied by the power plant 12 in the best conditions Func ^¬ tioning of the power plant 12; - the electrical power that may take the instal lation ^¬ 10 from the power grid 18 is limited. Since the electric power delivered by the power plant 12 is positive, the withdrawal limit corresponds to the maximum electric power of the energy storage system 14 from the electrical network 18. This limit may be zero. In this case, the energy storage system 14 can not be charged from the power grid 18.

In addition, the determination of the prediction of the electrical power supplied by the installation 10 during the time interval ΔΤ _] _ by the energy management module 22 is carried out while respecting several additional constraints which may be imposed by the operation of the energy storage system 14. Examples of constraints are as follows:

 the charging electric power of the energy storage system 14 must be less than a maximum charging power;

 the electric discharge power of the energy storage system 14 must be less than a maximum discharge power;

 The state of charge SOC of the energy storage system 14 must remain above a minimum state of charge; and

 The state of charge SOC of the energy storage system 14 must remain below a maximum state of charge.

Generally speaking, a financial agreement can be concluded between the manager of the installation 10 and the manager of the electricity network 18. The electrical power supplied by the installation 10 is then remunerated by the manager of the electricity network 18. However, manager instal lation ^¬ 10 can be penalized when the electric power actually supplied by the plant 10 during the time interval _ΔΤ] _ deviates from the announced production plan, eg where, during the bearing to the power P _ref, ^has the electric power actually supplied by the plant 10 varies with respect to the reference power P _ref more than 2.5%. For example, when an event of non-compliance with the announced production plan is detected, only half of the electrical energy delivered by the installation 10 during the hour during which the event took place is remunerated. .

 Figure 4 shows, in the form of a schematic block, a more detailed embodiment of step 32.

In step 40, the management module 22 determines the maximum expected electrical power PENRmax that can be supplied by the power plant 12 during the time interval ΔΤ _] _. The module 22 compares the maximum electric power ^p ENRmax with a fraction, for example 40%, of the maximum electrical power MAX that can be supplied under the best conditions by the power station 12. If the maximum electrical power expected PENRmax ^is strictly higher. to 40% of the maximum power PMAX, the method continues in step 42. If the maximum electrical power provided PE ^es t Rmax not exceeding 40% of the maximum power PMAX, I ^e method continues to step 44.

In step 42, the module 22 sets the reference power P _re f to 40% of the maximum power PMAX - In step 44, the module 22 sets the reference power P _re f equal to the maximum electrical power expected ^p ENRmax ·

 FIG. 5 represents, in the form of a schematic block, a more detailed embodiment of step 34 of the method described previously with reference to FIG. 2.

In step 50, the module 22 determines the instants t _a and t _j delimiting a time interval during which the power plant 12 is adapted to supply the electrical network 18 with the electrical power P _re f- By way of example, moment t _a corresponds to the instant at which the power electrical power PENR exceeds the electric power P _re f and the instant t _a corresponds to the instant at which the expected electrical power PENR falls below the electrical power P _re f. The process continues in step 52.

In step 52, the module 22 determines whether, in view of the SOC-j_ _n -j_ state of charge of the energy storage system 14, the energy storage system 14 can store the excess electrical power supplied. by the power station 12, that is to say the surplus electrical power supplied by the power plant 12 beyond the electrical power P _re f between times t _a and ¾. As the state of charge SOC-j_ _n -j_ is measured at a time when the power station 12 no longer provides electrical energy, the state of charge SOC-j_ _n -j_ is substantially equal to the state of charge of the energy storage system 14 when the energy storage system 14 begins to receive or supply electrical energy during the time interval ΔΤ _] _. If the SOC-j_ _n -j_ state of charge of the energy storage system 14 allows the storage of all of the excess energy between the instants t _a and ¾ while complying with the other constraints described above, the method continues in step 54. If the state of charge SOC-j_ _n -j_ of the energy storage system 14 does not allow the storage of all of the excess electrical energy, the process continues at step 56.

In step 54, the module 22 determines that the instant t] _ of beginning of supply of the electrical power P _re f P ^AR the installation 10 is equal to t _a .

In step 56, the module 30 decreases the value of the instant t _a by a fixed quantity and the process returns to step 52. The instant t _a is decreased so that the maximum, or even the totality, of the excess electrical energy supplied by the power station 12 is recovered in the energy storage system 14 while complying with the other constraints described above. In FIG. 3, there is shown an instant t] _ strictly less than the instant t _a . The fact that the instant t] _ is less than the instant t _a means that, at least during the period from the instant t] _ to the instant t _a , the power station 12 is not able to reference power supply P _re f- the energy storage system 14 must complete and provide a portion of the electrical power to the grid 18 so that the total electric power provided by the facility 10 is well equal to the reference power P _re f- However, as the state of charge of the energy storage device 14 will decrease between times t] _ and t _a, that means between the instants t _a and ¾, the system energy storage 14 is able to store a greater part of the excess power supplied by the power plant 12 between times t _a and ¾.

 The evolution of the state of charge of the energy storage system 14 can be determined by the module 22 by using the charging and discharging laws of the energy storage system 14. An example of the law of charge of the system energy storage 14 is given by the following relation (1):

makes _rh XP " _h X At

 SOC (t + ût) = SOC (t) + - - (1)

 VS

where SOC is the state of charge of the energy storage system 14, rend ^ is the load efficiency of the energy storage system 14, P _Q ^ is the load capacity in absolute value of the storage system of the energy storage system 14 energy 14 and C is the total electrical energy that can be stored in the energy storage system 14. The load efficiency makes a real number that can vary from 0 to 1. The load efficiency makes it possible to be constant or vary according to the load power P _c -

An example of a discharge law of the energy storage system 14 is given by the following relation (2):

SOC (t + ût) = SOC (t) ^Pdech x ^A t ^ 2) makes _dech XC _gQ rendd where h is the discharge efficiency of the energy storage system 14 and P ^ t ^are ech discharge power absolute value of the energy storage system 14. The discharge efficiency makes ^ _g ^ is a real number can vary from 0 to 1. the discharge efficiency makes ^ _g ^ may be constant or vary depending on the discharge power P ^ ECH-

FIG. 6 represents, in the form of a schematic block, a more detailed embodiment of step 36 of the method described previously with reference to FIG.

In step 60, the module 22 determines whether the state of charge SOC1 of the energy storage system 14 provided at instant ¾ is equal to a desired state of charge SOC- _| - _ar g _e - _| -. If the state of charge SO¾ is equal to the desired state of charge SO¾arget 'the process continues in step 62. If the state of charge SO¾ is different from the desired state of charge SOC- _| - _ar g _e - _| the process continues in step 64.

 In step 62, the module 22 determines that the instant t2 is equal to the instant ¾.

 In step 64, the module 22 determines whether the state of charge SOC ^ is strictly greater than the state of charge referred to

SO¾arget · If the state of charge SO¾ is strictly greater than the state of charge SOC- _| - _ar g _e - _| the process continues in step 66. If the SOC charge state is strictly lower than the desired state of charge SOC- _| - _ar g _e - _| the process continues in step 68.

In step 66, the module 22 increases the value of the instant ¾, for example by a determined step. This means that the time during which the installation 10 provides the electrical reference power P _re f ^is increased and therefore that the charge storage system 14 will discharge to ensure this production of electrical energy. The process returns to step 60.

In step 68, the module 22 decreases the value of the instant ¾. This means that the time during which the plant 10 provides electrical power reference? Ref ^ ^are reduced and a portion of the surplus power provided by the power station 12 is used to recharge the energy storage system 14 and increase its state of charge.

FIGS. 7 and 8 are timing diagrams of signals during the implementation of the method according to the embodiment described above for the same meteorological forecasts (ie for the same curve of evolution of the expected electrical power PE R supplied by the power station 12) and for two different SOC-j_ _n -j_ charge states. For the curves of FIG. 7, the initial state of charge SOC-j_ _n -j_ is 50% while, for the curves of FIG. 8, the initial state of charge SOC-j_ _n -j_ is 90%. %.

 In each of FIG. 7 or 8 are also represented:

the curve of evolution of the electric power PE R 'actually produced by the power station 12;

the curve of evolution of the electric power ^P ENR + ST supplied to the network 18 by the installation 10 (the power being negative during a charging operation of the energy storage system 14);

 the evolution curve of the predicted electrical power P t delivered by the energy storage system 14;

 the evolution curve of the electric power Pst 'actually supplied by the energy storage system 14;

the state of charge SOC of the storage system 14; and successive phases A, B, C, the phase A corresponding to a ramp-up phase of the electrical power supplied by the installation 10, the phase B corresponding to a phase of supply by the installation 10 of the electrical power P _re f substantially constant and the phase C corresponding to a phase of reduction of the electrical power supplied by the installation 10.

It can be seen that the energy storage system 14 can not store the electrical power demanded around 4 pm, the state of charge of the energy storage system 14 having already reaches 100%. This may be due to the fact that the charge and discharge laws used for the determination of the production plan are only approximations of the evolution of the actual state of charge of the energy storage system 14. be because the actual output of the power station 12 is different from the expected production from the meteorological data. The module 22 then controls the power plant 12 so that it reduces the electrical power supplied PENR '' ^CE allows the total electrical power? ENR + St delivered by the installation 10 to remain within the limits allowed around the reference power P _re f-

For the curves relating to FIG. 8, since the initial state of charge SOC-j_ _n -j_ of the energy storage system 14 is greater than that of the curves of FIG. 7, the instant t] _ in FIG. is less than the instant t] _ in FIG. 7. This makes it possible to discharge the energy storage system 14 for a longer duration between the times t] _ and t _{a in} order to be able to store the excess of electrical energy between instants t _a and ¾.

Particular embodiments of the present invention have been described. Various variations and modifications will be apparent to those skilled in the art. In particular, the method for determining the instants t _a and ¾ may be different from what has been described previously. For example, the instants t _a and t _j may be determined by an analysis of the evolution curve of the electrical power provided provided by the power plant 12 during the time interval _ΔΤ] _.

Claims

A method, implemented by a processor or an electronic circuit, for determining the electrical power (PENR + ST) provided by an electrical energy supply installation (10) comprising an energy storage system (14). ) and a power plant (12), said method comprising:

determining, from meteorological forecasts over a first time interval (ΔΤ _] _), the expected evolution of the electric power (PENPJ produced by the power station during the first time interval;

determining, from the expected evolution, at least one electrical power level (Pref) ^e ^ of at least one second time interval (Δ 2), contained in the first time interval, during which the power plant is capable of supplying electrical power at said level; and modifying the initial terminal (t _a ) and / or the final terminal (¾) of the second time interval according to the desired evolution of the state of charge (SOC) of the energy storage system, determined from a model of the energy storage system, during the first time interval.

 2. Method according to claim 1, comprising the following successive steps:

receive weather forecasts on the first time interval (ΔΤ _] _);

 determining the expected change in electrical power (PENPJ produced by the power plant (12) during the first time interval from the weather forecasts;

 determine the electrical power level (Pref) from the expected evolution; and

determine the second time interval (Δ 2) from the expected evolution and the electric power level.

The method of claim 1 or 2, further comprising the step of:

decreasing the initial bound (t _a ) if the state of charge (SOC) of the energy storage system (14) is greater than or equal to a first threshold for at least one time of the second time interval (Δ 2) other than the final bound (¾).

 The method of claim 1 or 2, further comprising the step of:

increasing the initial bound (t _a ) if the state of charge (SOC) of the energy storage system (14) is strictly less than or equal to a second threshold during the second time interval (Δ 2).

 The method of any one of claims 1 to 4, further comprising the step of:

 modifying the final terminal (¾) as long as the state of charge (SOC) of the energy storage system (14) at the final terminal is different from a third threshold.

 The method of claim 5, wherein the step of modifying the final terminal (¾) comprises the following steps:

 increasing the final terminal as long as the state of charge (SOC) of the energy storage system (14) at the final terminal is strictly greater than the third threshold.

 The method of claim 5 or 6, wherein the step of modifying the final terminal (¾) comprises the following steps:

 decreasing the final terminal as long as the state of charge (SOC) of the energy storage system (14) at the final terminal is strictly less than the third threshold.

 The method according to any one of claims 1 to 7, wherein the step of modifying the final terminal (¾) is performed after the step of modifying the initial terminal.

(t _a ) -

9. A method according to any one of claims 1 to 8, wherein the electric power level (P _r ef) ^is strictly less than or equal to the maximum of the expected evolution of the electrical power (PENPJ ^e t ^ ^e second time interval (Δ 2) corresponds to the time interval during which the expected electrical power exceeds said level.

 A method of supplying energy by an electrical power supply installation (10) comprising an energy storage system (14) and a power plant (12) comprising the steps of:

 determining the electric power supplied by the electric power supply installation according to any one of claims 1 to 9; and

supplying electric power at the electrical power level (P _re f), with an error range of less than 5 ~ 6 r during the second time interval.

 11. Computer support for storing a computer program for carrying out the method according to any one of claims 1 to 9.

 12. Installation (10) for supplying electrical energy comprising an energy storage system (14) and a power plant (12), the installation comprising at least one processor programmed for or an electronic circuit adapted to:

determining, from meteorological forecasts over a first time interval (ΔΤ _] _, the expected evolution of the electrical power (PENPJ produced by the power station during the first time interval;

determining, from the expected evolution, at least one electrical power level (P ef) ^e ^ ^at least one second time interval (Δ 2), contained in the first time interval, during which the power plant is capable of providing the electrical power at said level; and

modifying the initial terminal (t _a ) and / or the final terminal (t _j ) of the second time interval according to the desired evolution of the state of charge (SOC) of the energy storage system, determined from of a model of the energy storage system, during the first time interval.

13. Installation according to claim 12, wherein the power station (12) can be a power plant using solar energy, wind energy, wave energy, water energy, energy of energy. marine currents and / or tidal energy.

 14. Installation according to claim 12 or 13, wherein the energy storage system (14) comprises a system selected from the group consisting of electric batteries, a flywheel system, a compressed air system, a station pumped energy transfer system and a fuel cell and electrolyzer system.