ES2685868A1 - METHOD AND DEVICE FOR INTELLIGENT ELECTRICAL PROSUME (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Method and device for intelligent electric consumption, intelligent management of loads in self-consumption facilities. The method includes determining the manageable loads of the installation and its energy demand in a management period; obtain the consumption of the installation; determine the self-consumption potential of the installation according to the generation capacity and energy accumulation and the consumption of the installation; generate, for each manageable load, an optimized consumption profile that determines the moments of connection and disconnection of the manageable load in the management period, calculated on the basis of the self-consumption potential available in the installation, the energy demand of the manageable loads and an optimization criterion; and connect the manageable loads in the management period according to the consumption profile generated for each manageable load. (Machine-translation by Google Translate, not legally binding)

Description

5

10

fifteen

twenty

25

30

METHOD AND DEVICE FOR SMART ELECTRICAL PROSURE

DESCRIPTION

FIELD OF THE INVENTION

The present invention is encompassed in the sector of electricity self-consumption systems, applied both in the domestic and in the industrial field. In particular, the object of the present invention is a device and method for the intelligent control and management of installation loads.

BACKGROUND OF THE INVENTION

The objectives established in Europe in the Framework of action of the European Union in the field of climate and energy until 2030, together with the commitment of the different public administrations to promote the transition towards a new sustainable energy model and to the forecast of the increase of energy costs make it necessary to develop technologies for generating electricity that do not emit greenhouse gases.

One of the technological developments with greater acceptance and demand on the part of society to fight against climate change, dependence on fossil fuels, carbonization of power generation systems and energy poverty, consists of the installation of self-consumption systems of electricity, leading to the emergence of the prosumer (that is, producer and consumer) of energy. The prosumer is defined as the agent that, simultaneously, has the capacity to generate part or all of the energy it needs.

Currently, the prosumer can choose between two modes of self-consumption: with injection and without grid injection. The first one, as its name implies, allows the user to export the surplus generation of his installation to the distribution grid that he has not been able to take advantage of with his consumption installation, either under an energy purchase-sale contract with the distribution company, either through other agreed mechanisms such as the net balance. The second modality prevents the possibility of exporting surpluses, so the prosumer must have devices that prevent the injection of energy into the network. These devices totally or partially limit the

5

10

fifteen

twenty

25

30

35

prosumer generation capacity, especially if it is not capable of storing excess energy.

Although the network access tolls are much lower (even sometimes null by exemption) in the case of zero-network injection facilities, the attractiveness of the profitability of this type of facilities is reduced by the high cost and complications associated with the need for the incorporation of energy accumulation systems, usually of an electrical nature, as it is the most flexible and profitable method. Otherwise, the efficiency of the prosumer installation decreases dramatically or, which is more pernicious, forces you to consume above your needs.

In the case of grid injection, there are unmanaged facilities with the possibility of injecting excess energy into the electricity grid. These installations simply consist of the connection of generation equipment inside an electrical consumption installation, so that an "uncontrolled" injection of energy is made to the distribution network provided that the generation exceeds consumption.

The network injection control can, however, be managed by means of control devices, especially if electrical accumulation systems are available. Battery managers decide if generation excesses accumulate or are discharged to the network based on their charging status. Battery managers can be classified as “non-intelligent”, if they only take into account the available accumulation capacity, or “intelligent”, if in addition to the state of charge they consider some other criteria to proceed with the accumulation or discharge of energy, normally the price of the electric tariff.

On the other hand, although uncommon, some facilities with injection capacity have dynamic load managers that proceed to the connection of consumption circuits when there are excesses of generation with respect to the unmanageable consumption of the installation.

Facilities limited to the zero injection of excess energy must necessarily have mechanisms that prevent injection. Usually there are anti-aging devices that act on the generators of the prosumer installation when they detect that the energy generated reaches the value of the energy consumed in the installation. These devices can be "dynamic" if they regulate the generator so that

5

10

fifteen

twenty

25

30

this one adapts to the level of existing consumption, or "static", if to avoid the injection they must disconnect the generator completely. Strictly, it is not considered that this type of devices make a management of the installation, except for the mentioned regulation of the generators for comply with the legal requirements and those established by the distribution company.

In order to increase the efficiency of the generation, management teams can be arranged, installed in series with the anti-seasoning. These devices can manage the accumulation of excess energy in batteries (battery managers) and / or the dynamic on and off of loads. As previously indicated, battery managers can be "non-intelligent" if they only monitor the charging status of the accumulation system, or "intelligent" if other parameters are taken into account. Dynamic load managers, on the other hand, proceed to power consumption of interest to the user, taking advantage of the surplus generation capacity.

With regard to anti-aging systems, some of the commercial equipment that currently exists in this category are the Solar Log Meter and the CDP-0 which, mainly focused on photovoltaic installations, regulate the operating point of the inverter according to the consumption balance. measured generation in the installation.

As for battery managers or regulators, various accumulation systems are known that are capable of optimizing the functions of charging and discharging based on various criteria, mainly economic ones. Thus, patent document ES2434668-A2 presents a system of accumulation and saving of electric energy composed of a set of regulated electric batteries depending on the comparative measure of the voltage levels.

Other battery managers, such as those presented in patent documents ES2333754-T3 and ES-2553808-A1, present a device for charging batteries at night, including the difference in intraday energy prices.

The management of batteries can be done by consuming (accumulating) energy only from the power grid, or include the management of one or more micro-generators connected to the internal network, such as that presented in patent document ES2403906-T3.

5

10

fifteen

twenty

25

30

Patent document ES2540601-T3, for its part, presents a circuit and method for the accumulation and discharge of electrical energy depending on the availability of a renewable energy source and the requirements for distribution or consumption of energy, in order to minimize consumption of network power.

The management of the accumulation systems can be carried out locally, at the installation level, or coordinated from a centralized control, as stated in patent document ES2405538-A2, which could help flatten the demand curve and, by therefore, to perform an optimized production capacity planning with less oversized generating units.

Finally, other accumulation management systems present the possibility of maximizing efficiency by hybridizing the system with thermal accumulation, taking advantage of the residual heat of the equipment power electronics. Thus, patent document ES2546747-A1 presents a heating and hot water producer that stores electrical energy in batteries for later consumption by transforming the direct current into alternating current, and that has the ability to manage the accumulation of energy and even the ignition of electric charges according to the instructions of a logical control unit implementing an unspecified method or algorithm.

With respect to dynamic load managers, there are currently commercial equipment that allows to control the ignition of some loads of the installation exclusively evaluating the possible existence of surplus generation, such as the ITR 2.0 injection system, the CDP equipment -G or the Sunny Home Manager device. These devices can also be presented as accessories for anti-aging devices, such as the Solar-Log Smart Home Relay Box and the Solar-Log Smart Relay Station.

Patent document ES2437184-A2 is based on the same principle and develops the mode of operation of an anti-aging equipment, adjusting the generation to the load needs. Its objective is to ensure that the electricity production carried out in an internal network does not access the external network, for which the procedure determines whether the level of internal production is adequate by adjusting such level by increasing or decreasing consumption, or increasing or production decline

5

10

fifteen

twenty

25

30

The system disclosed in document ES1138814-U, for its part, allows the user to define fixed load profiles and, based on them, proceed to the ignition of said loads when there is available generation. On the other hand, the self-consumption control system disclosed in ES2482017-A1 includes a load manager that, by means of a sensor that measures the energy consumed by the installation and another sensor that measures the energy produced by a generating equipment, acts in such a way , that when the energy or current detected by the second sensor is greater than the energy or current of the first, it gives order for the remaining energy to be stored in one or several electric thermoses or another device of great consumption.

Patent documents ES2555290-T3 and ES2219674-T3 disclose a cargo manager so that the first one manages the joint operation of large consumers participating in the energy market and the second avoids exceeding the maximum contracted power or maximum instantaneous energy consumption, proceeding to the control and in his case, disconnection of the loads of the installation.

Other load managers are those presented in ES2246740-A1 and ES-2278526-A1. This category of load managers can also include applications that evaluate the operating status of the system and, without performing any automatic management, notify the user by sending alerts of excessive consumption or certain favorable conditions of ignition of consumption of According to your profile. Of this type are the equipment presented in ES2400586-A1 and ES-2414581-A2.

However, all these equipments lack the capacity to carry out an effectively “intelligent” management of loads, so that this management has as an objective the non-dependence of an energy accumulation system, or, where appropriate, minimizes said need. The systems and methods developed so far are characterized by:

a) Carry out a management based on the existing energy flow in the installation, so that, by evaluating the energy consumed and the energy produced, it is operated either on the accumulation, or on certain consumption equipment.

b) Optimize the state of charge of the accumulation systems, in case of having such systems.

5

10

fifteen

twenty

25

30

35

It is essential therefore a new method and system that allow the management of loads effectively intelligent (dynamic managers of intelligent loads), and in particular that provide:

a) Provide for the generation-consumption balance and not to operate according to the existing balance, but according to the self-consumption capacity of the installation.

b) Carry out a load management that eliminates the use of energy storage systems (batteries) or minimizes the necessary capacity for energy storage.

c) Carry out an optimized load management based on one or several criteria simultaneously (economic or other), ensuring that all technical constraints and global demands are met within the operating cycle.

DESCRIPTION OF THE INVENTION

The invention relates to a device and a method for intelligent electrical prosumption, and in particular, for intelligent dynamic management of electrical consumptions in self-consumption installations, by means of a first evaluation of the manageable nature of said consumptions or loads and the application of a process which automatically performs the dispatch of energy in the installation of a prosumer, eliminating or minimizing, where appropriate, the need for electrical accumulation in the form of batteries or the like, while obtaining the optimization of one or more specific parameters (such such as the economic cost of energy demand management, the equivalent CO2 emissions of the installation, the self-consumption quota, the use of self-generation resources or the self-generation ratio), maintaining the level of satisfaction of the user's demand final, provided that the technical conditions admit it.

The facilities to which the present invention is applied are installations with access to the electricity grid and which have self-consumption capacity, for which they have their own system of generation of electrical energy or an accumulation system of electrical energy (batteries ), or both systems (generation and accumulation of electrical energy).

A first aspect of the present invention relates to a method for intelligent electrical prosumption, of intelligent load management in self-consumption facilities. The method comprises the following stages:

- Determine the manageable loads of the installation and obtain the energy demand of each manageable load for a given management period.

- Obtain the consumption of the installation.

5

10

fifteen

twenty

25

30

35

- Determine the self-consumption potential of the installation based on the power generation capacity, energy accumulation and consumption of the installation.

- To generate, for each manageable load, an optimized consumption profile that determines the moments of connection and disconnection of the manageable load in the management period, where said moments of connection and disconnection of the manageable load are calculated based on the potential for self-consumption available in the installation, the energy demand of the manageable loads and an optimization criterion.

- Make the connection and disconnection of manageable loads in the management period according to the consumption profile generated for each manageable load.

In one embodiment, the connection of an i-th manageable load at a given time t is made when the following condition is met:

(PCGi-Pautoconsumo) • F (t) <= PCGi Fmin.

Where PCGi is the energy demand of the i-th manageable load, Pautoconsumo is the installation's self-consumption potential, F (t) is the value of the optimization criterion at time t; Fmin is the value of the minimum optimization criterion in the period between the instant of execution t and the end of the management period. The potential for self-consumption of the installation can be obtained by subtracting the consumption of the installation from its capacity and the energy accumulation available.

The method may comprise obtaining a priority assignment of the manageable loads, so that the connection of the manageable loads is ordered according to the priority assigned to each manageable load.

In one embodiment, the method may comprise obtaining the cost of electric energy for the determined management period, and where the optimization criterion includes the cost of energy. In another embodiment, the optimization criterion may comprise the mass of equivalent CO2 emitted by the manageable loads. In another different embodiment, the optimization criterion could comprise the actual efficiency of the installation generation system, or any combination of the above criteria. The optimization criteria may also include other criteria.

A second aspect of the present invention relates to a device for intelligent electric prosumo, for intelligent load management in self-consumption facilities. The device, which implements the method described above, comprises the following

8

5

10

fifteen

twenty

25

30

35

elements:

- A user interface to obtain the manageable loads of the installation and the energy demand of each manageable load for a given management period (typically 24 hours).

- Reading means configured to obtain the consumption of the installation through the reading of the energy meters of the installation.

- Data processing means configured to determine the potential for self-consumption of the installation based on the power generation capacity, energy accumulation and consumption of the installation; and to generate, for each manageable load, an optimized consumption profile that determines the moments of connection and disconnection of the manageable load in the management period, where said moments of connection and disconnection are calculated based on the self-consumption potential available in the installation, the energy demand of the manageable loads and an optimization criterion.

- Means of activation of the manageable loads, configured to send connection and disconnection orders of the manageable loads in the management period according to the consumption profile generated for each manageable load.

The management process iteratively evaluates the real priority of the manageable loads of the system, the actual consumption at each moment, the projection of the generation capacity and other parameters (such as energy cost), and decides the activation, regulation or displacement of the managed load to a period of energy consumption of the optimal network (economically, environmentally or based on any other predefined criteria) at every moment, avoiding, in the case of facilities not enabled for the injection of surplus generation to network, the entry into operation of anti-aging equipment. The displacement of the load refers to postponing the consumption of the load at a later time more conducive to the optimization of the chosen criteria. In the case of performing an economic optimization management of the cargo dispatch, the system takes into account the user rate system to optimize its consumption profile.

The intelligent load manager stipulates whether one or more loads connected to the system, considered manageable loads, must be connected, regulated or moved according to the following criteria:

- The establishment of an order of priority of each consumption or electric charge, and of the energy needs of each of these manageable loads, selected, either by the user, or intelligently by the own

5

10

fifteen

twenty

25

30

procedure, such as the need to fill a water reserve prior to the execution of a manageable irrigation, or the prediction of the needs obtained from the automatic learning of the system.

- The forecast of generation of electrical energy ready to be self-consumed in the future.

- An optimization criterion, such as the current and future cost (economic, environmental, etc.) of energy.

In summary, the methodology followed in the procedure presented in the invention optimizes the self-consumption of the installation through the connection, regulation or displacement of manageable loads based on the potential for self-consumption available, the energy needs of the manageable loads and optimization criteria.

The procedure addresses the programmed consumptions for each load, in the time and amount of energy needed to meet the needs of each application. The method establishes the periods in which the manageable loads must be connected, either from energy generated in the installation or from energy acquired from the distribution network, at the moments in which it is considered more convenient, following criteria of optimization defined, preferably the minimization of energy cost and / or opportunity of energy, reduction of pollutant emissions, environmental or other criteria, individually or in combination.

In the case of installations not enabled for the injection of energy into the distribution network, the system avoids the actions of the anti-aging equipment, thus maximizing the potential for self-consumption of the installation and reducing or eliminating the need for the installation of electrical energy accumulation.

The implementation of the present invention implies an energy optimization of any self-consumption installation. Although it can manage and / or work in parallel with energy accumulation systems, the invention allows the minimization of these or even their suppression in a competitive way, thus greatly reducing the investment costs of the self-consumption facilities.

5

10

fifteen

twenty

25

30

In an optimization of an economic nature, applied to a criterion of optimization of energy cost reduction, the process of the present invention comprises the following functionalities:

a) Construction of the energy cost profile: by downloading external data (downloading the energy price table for the management period) the rate regime and energy cost are obtained, generating the actual profile of energy cost that will be considered as optimization criteria.

b) Measurement of existing consumption data: automatically, the system measures and records the consumption data of the corresponding installation.

c) Establishment of consumption priorities and generation of load profiles: based on predefined provisions of priority of consumptions and intrinsic conditions of the own characteristics of the manageable loads, the procedure establishes an order of satisfaction of the demand of the managed loads, generating optimized consumption (or activation) profiles for each of them.

d) Evaluation and projection of the capacity of self-generation of energy: either through measures of the existing generation and availability of the energy resource, or by obtaining external data or the use and generation of deterministic or stochastic models, the procedure evaluates the capacity of Existing generation not limited by the characteristics of consumption and establishes the capacity for self-generation of energy.

The device proposed in the present invention constitutes a paradigm shift with respect to existing equipment, by optimizing load management based on the self-consumption of the installation and one or several optimization variables that are not restricted to the economic cost of the energy consumed from the external network, but may include the environmental impact of said energy, the self-consumption quota of the installation, the actual efficiency of the generation system, among other optimization criteria. In addition, the present invention allows loads to be classified according to their absolute and relative priority and the ability to regulate or interrupt.

The device also incorporates the following features:

- Ability to measure existing consumptions in the installation.

5

10

fifteen

twenty

25

30

35

- Ability to measure the generation and / or accumulation of energy existing in the installation at all times.

- In the case of operation with optimization criteria of the economic cost of the energy consumed from the external network, the device can perform the download, typically daily, of the current values of the electricity market price, normally given on an hourly basis, according to the tariff regime hired by the user. Similarly, with other optimization criteria, the values of the variable or optimization variables, such as CO2 mass emissions depending on the energy mix, in time terms, or other similar parameters, would be obtained or calculated.

- Ability to allow the user to cancel the automatic management of the load or loads they want, temporarily or permanently.

BRIEF DESCRIPTION OF THE DRAWINGS

Next, a series of figures that help to better understand the invention and that expressly relate to an embodiment of said invention that is presented as a non-limiting example thereof are described very briefly.

Figure 1 schematically represents the inputs and outputs of the device for intelligent electric prosumption according to the present invention.

Figure 2 shows, according to a possible embodiment, a flow chart with the steps of the procedure for intelligent electrical prosumption.

Figure 3 illustrates a flowchart of the subroutine that calculates an optimal value of the optimization criterion.

PREFERRED EMBODIMENT OF THE INVENTION

The present invention relates to a device and a method for intelligent electrical prosumption, of load management of an electrical installation, valid for both domestic and industrial use, since it can operate on all types of loads, activating them at the most appropriate time according to its consumption, the price of electricity at any time or other optimization criteria.

Manageable loads are understood as all those devices that require electric power to maneuver, whose operation (including on and off) can

12

5

10

fifteen

twenty

25

30

35

be controlled, and its habit of use is not restricted to a specific moment, but can be planned in different time slots (for example, advance or delay the ignition with respect to the usual time of work). Thus, for example, in the domestic sphere, manageable loads may include various appliances (such as dishwashers, washers and dryers) that do not require operation at a specific time.

The device for intelligent electric prosumo is integrated in a system of generation of the installation, being able to decide whether to self-consume energy from said generation system (or even accumulation if necessary) or from the network itself, optimally at every moment in function of an optimization criterion, typically the cost of energy.

Figure 1 shows a block diagram in which the device (1) is represented for intelligent electric prosumo, intelligent management of loads in self-consumption facilities, which have their own power generation system (for example, modules photovoltaic) and, optionally, batteries for storing the generated energy.

In Figure 1 the different input variables of the device (1) are identified:

- Data of the optimization criteria (2): for example, data on the cost of energy and rate scheme, opportunity cost of energy, emissions associated with external energy consumption, etc.

- Definition of the manageable loads or circuits (3), operation characteristics and their theoretical priority. These are user-defined variables, since the installation will have essential loads for the user whose operation cannot be relocated, and as such they are not manageable loads by the device (1) (such as the induction hobs of the kitchen, lighting, microwave, etc.)

- Restrictions of operation of the installation (4), such as the generation capacity, the possible simultaneity of loads, the maximum contracted power, or consumption conditions and hours of operation in the manageable loads.

- Measurement of the existing consumption in the installation (5).

- Measurement of the existing generation in the installation (6).

- Current situation of the capacity of the energy accumulation system (7) (if any). In case of excess power generation, the excess energy would be stored in the energy accumulators of the installation, if available. In that case the accumulated energy will be taken into account in the

13

5

10

fifteen

twenty

25

30

35

self-consumption potential of the installation.

As an output variable, the device (1) controls the switching on or off of the manageable loads, by means of connection or disconnection orders (8). All operation data and measurements captured by the device (1) can be exported to an external monitoring platform, such as a server (9).

Figure 2 shows a flow chart with the steps of the procedure (10) for intelligent electric prosumption implemented by the device (1), an electronic or computer equipment capable of handling input signals and emitting control signals to devices, such as relays acting on contactors capable of connecting or disconnecting the power supply of the manageable loads. In order to feed the management procedure, the device (1) also has an interface for access to the precise data for the realization of the automatic control, which can include the reading of the overall consumption of the installation, measures of the potential of generation, user-defined parameters (including the definition of manageable loads, their consumption profiles and their standard connection priority) as well as any other information necessary for optimal management, such as tariff information of consumption.

The management procedure is a cyclic process, which begins first in an initialization stage (12) in which the variable i (i = 1) is initialized, where said variable i corresponds to the number of the manageable load (CGi) analyzed in each iteration.

The procedure (10) includes the definition of the manageable loads and the obtaining of the energy demand (13) of each one of them. In this stage the number N of loads or manageable circuits is also obtained. Thus, for example, in a domestic application, the user can define the air conditioning as a manageable load, and the procedure obtains the energy demand assigned to it, which will depend on the specific program selected by the user. All the energy demand information of the loads can be stored in a database, so that the procedure obtains the program selected by the user, consults the database, and recovers the energy demand assigned to that device and the selected program .

This first stage may also include evaluation and priority setting, by assigning priorities (13) of manageable loads based on the

5

10

fifteen

twenty

25

30

35

user preferences and the interrelationship between them, since the manageable loads can be dependent on each other. For example, if a washing machine is also included, order of priority 1 can be assigned to the dishwasher and order of priority 2 to the washing machine, depending on the preferences or needs of the user or through an automatic system learning process.

Next, the actual consumption of the installation (14) is read, accessing the information provided by the installation measuring devices (eg energy meters), and the load management process is started evaluating the i-th manageable load, checking (15) if i <= N, to determine if the iterations have been made for the N manageable loads, in which case the number of manageable load (i = 1) is initialized (16) to start again the iterations of the planning of the different manageable loads, in case there is any PCGi energy demand left unmet.

In step (17) it is checked whether PCGi> 0, that is, if it is necessary to satisfy the energy consumption or demand profile of the i-th manageable load. If the energy demand of the ith load has been satisfied (PCGi = 0), the counter i (i = i + 1) is increased (18). Otherwise, it is evaluated (19) if Pmax_contracted + Pautoconsumo> = PCGi, to determine the availability of power of the installation to supply the energy demand of the load (PCGi), taking into account the maximum contracted power of the installation (Pmax_contracted ) and the power that could be provided by the installation generation system (Pautoconsumo).

If sufficient power is available to meet the demand of the manageable load, an optimal value Fmin of the optimization criterion or function is calculated that, in the case of optimal management according to economic cost, would correspond to the price of energy Optimum available for satisfying the demand of the manageable load, taking into account its consumption profile. Thus, for example, if said manageable load i at the instant of execution t of the described management procedure needs to be activated at constant nominal power for hi hours, Fmin would correspond to the hourly energy price of the first hour of the hi hourly prices cheaper than the remaining period, before the restart of load demands (the management period usually includes the day).

Figure 3 represents, according to a possible embodiment, a flow scheme of a subroutine that performs the computation of Fmin. To determine Fmin, according to the example of the

5

10

fifteen

twenty

25

30

Figure 3, the matrix m0 is made up of the pairs of time values, t, and optimization criterion value F at the corresponding time t. Said matrix of paired data m0 = (t, F) is ordered (25) according to increasing order Fen, obtaining the matrix m1 = (t, F). According to the above example of energy cost optimization, the matrix would be sorted by energy price, in increasing order of hourly prices F. Next, the previous matrix is truncated (26) by selecting only the first rows, obtaining the truncated matrix m2 = mi (1: hi, 1: 2), to then rearrange (27) the matrix m2 temporarily, according to t in an increasing way, obtaining the rearranged matrix m3. Finally, the value Fmin (Fmin = m3 (1,2)) is obtained (28), which corresponds to the hourly price F of the energy of the first row of the resulting matrix.

As indicated, hi is the remaining operating time of the last manageable load. That is, if the load corresponds to a constant daily demand of 10 hours and has already been operating 8 hours, hi = 10-8 = 2 hours. When the self-consumption source (for example, solar energy) is no longer available or is not expected to exist, the remaining time hi must be satisfied with energy consumption from the power grid, optimally according to the established criteria. For this reason, firstly the matrix m1 is generated with the hours of the cheapest energy prices (or the corresponding optimization factor) ordered from lowest to highest associated cost (step 25), then truncating the matrix at hi hours that are required to meet the demand (step 26) and finally the resulting matrix m2 is reordered (step 27), but in this case in chronological order to perform the proper programming of the on (and off) of the load (matrix m3 ).

The following is a concrete example for the calculation of Fmin. In the example, the manageable load needs to be connected 10 hours on the day of management, and 7 hours have already been satisfied, so hi = 10-7 = 3. The following matrix m0 = (t, F), ordered temporarily (from 0:00 to 12:00), is obtained by downloading prices for the hourly electricity tariff:

m0 = (0:00, 4; 1:00, 5; 2:00, 6; 3:00, 2; 4:00, 7; 5:00, 8; 6:00, 3; 7:00, 1 ; 8:00, 9; 9:00, 10;

10:00, 11; 11:00, 12; 12:00, 13);

The matrix my ordered according to F is obtained in increasing order (step 25):

m1 = (7:00, 1; 3:00, 2; 6:00, 3; 0:00, 4; 1:00, 5; 2:00, 6; 4:00, 7; 5:00, 8 ; 8:00, 9; 9:00, 10;

10:00, 11; 11:00, 12; 12:00, 13);

5

10

fifteen

twenty

25

30

Next, the truncated matrix m2 is obtained with the first hi rows (step 26):

m2 = (7: 00,1; 3: 00,2; 6:00, 3);

The matrix m2 is rearranged according to increasing t (step 27), obtaining m3:

m3 = (3:00, 2; 6:00, 3; 7:00, 1);

Finally, the value of Fmin is obtained (step 28):

Fmin = 2.

Returning to the process of Figure 2, once the Fmin value (20) is obtained, the device quantifies (21) the convenience of switching on or keeping the manageable load (CGi) on if the part of the consumption of said load on demand of network or other source energy (accumulation system or similar) by the cost of said instant, F (t), is less than displacing the full consumption of said ith load instantly associated with the Fmin cost. For this, it is evaluated if the following condition is met:

(PCGi-Pautoconsumo) • F (t) <= PCGixFmin;

where:

PCGi is the energy requirement of the corresponding i-th manageable load [W]. Pautoconsumo is the potential of self-consumption of the installation, result of the subtraction to the generation capacity (Pgeneration) and accumulation (Accumulation) the total consumption (Consumption) of the installation [W]:

Pautoconsumption = Pgeneration + Accumulation-Consumption;

where:

Pgeneration is the generation capacity of the installation.

Accumulation is the current energy accumulation of the installation.

Consumption is the total consumption of the installation.

F (t) is the value of the optimization criterion at time t (in an exclusively economic optimization it would comprise the price of energy).

Fmin is the value of the minimum optimization criterion in the period between the instant of execution t and the end of the operating cycle of the procedure.

If the condition of step (21) is met, it is activated (22) or the manageable load CGi is on. Next, the satisfied demand of consumption CGi, hi = hi-1, where hi is the remaining operating time of the load, is discounted (23)

CGi manageable until the end of the procedure operation cycle. Finally, in step (18) the routine cycle is restarted by evaluating the next manageable load (i = i + 1). In the case of reaching the maximum number of manageable loads, N, the first one is reassessed (step 16).

5

It must be considered at all times that, in the case of an installation without injection of energy to the grid, the energy consumption must always be equal to or greater than the generation of the installation. Depending on the level of consumption, the generation may not be at its maximum available capacity. Therefore, it is necessary to estimate its maximum capacity of 10 generation at each moment, which will allow the system to determine the necessary energy consumption of the distribution network that meets the demand for the possible new manageable load in the system. The evaluation of the maximum generation potential can be determined by various methods, preferably through direct measurement of the energy resource to be exploited, predictive models based on indirect variables or data from external sources.

Claims (8)

5 10 fifteen twenty 25 30 35 1. Method for intelligent electric prosumption, characterized in that it comprises: determine (13) the manageable loads of a self-consumption installation and obtain the energy demand of each manageable load for a given management period; obtain (14) the consumption of the installation; determine the potential for self-consumption of the installation based on the power generation capacity, energy accumulation and consumption of the installation; generate, for each manageable load, an optimized consumption profile that determines the moments of connection and disconnection of the manageable load in the management period, where said moments of connection and disconnection of the manageable load are calculated based on the available self-consumption potential in the installation, the energy demand of the manageable loads and an optimization criterion; carry out the connection and disconnection of the manageable loads in the management period according to the consumption profile generated for each manageable load. 2. Method according to claim 1, characterized in that the connection of an i-th manageable load, in an instant of time t, is determined when the following condition is met: (PCGi-Pautoconsumo) • F (t) <= PCGi Fmin; where: PCGi is the energy demand of the i-th manageable load, Pautoconsumo is the potential for self-consumption of the installation, F (t) is the value of the optimization criterion at time t; Fmin is the value of the minimum optimization criterion in the period between the instant of execution t and the end of the management period. 3. Method according to claim 2, characterized in that the potential for self-consumption of the installation is obtained by subtracting the consumption of the installation from the installation generation capacity and the energy accumulation of the installation. 4. Method according to any of the preceding claims, characterized in that it comprises obtaining a priority assignment of the manageable loads; where the connection of the manageable loads is ordered according to the priority assigned to each manageable load. 5 10 fifteen twenty 25 30 5. Method according to any of the preceding claims, characterized in that it comprises obtaining the cost of electric energy for the determined management period, and where the optimization criterion includes the cost of energy. 6. Method according to any of the preceding claims, characterized in that the optimization criterion includes the equivalent mass of CO2 emitted by the manageable loads. 7. Method according to any of the preceding claims, characterized in that the optimization criterion includes the real efficiency of the installation generation system. 8. Device for intelligent electric prosumo, characterized in that the device (1) comprises: a user interface to obtain the manageable loads of a self-consumption installation and the energy demand of each manageable load in a given management period; reading means (14) configured to obtain the consumption of the installation through the reading of the energy meters of the installation; data processing means configured to: determine the potential for self-consumption of the installation based on the power generation capacity, energy accumulation and consumption of the installation; generate, for each manageable load, an optimized consumption profile that determines the moments of connection and disconnection of the manageable load in the management period, where said instants of connection and disconnection are calculated based on the self-consumption potential available in the installation, the energy demand of the manageable loads and an optimization criterion; means of activation of the manageable loads, configured to send connection and disconnection orders of the manageable loads in the management period according to the consumption profile generated for each manageable load.