CN117691685B - Intelligent regulation and control system for photovoltaic inverter - Google Patents

Abstract

The application relates to an intelligent regulation and control system of a photovoltaic inverter, which relates to the technical field of photovoltaics and comprises the following components: a plurality of household photovoltaic units; each household photovoltaic unit comprises: a photovoltaic inverter; the grid connection port of the photovoltaic inverter is connected with a power grid; the PV component is connected with a PV port of the photovoltaic inverter; the energy storage battery is electrically connected with the photovoltaic inverter; an electrical load; the power utilization load is connected with the photovoltaic inverter; the photovoltaic inverters of the photovoltaic units of a plurality of households are electrically connected with the photovoltaic inverters of the photovoltaic units of the adjacent households through power lines; each household photovoltaic unit performs electric energy self-use or performs electricity taking or discharging to the adjacent household photovoltaic units according to the power generation pre-measurement of the PV component, the storage electric quantity of the energy storage battery and the total electric quantity of the electricity utilization load; and under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the electricity is taken or discharged to the power grid.

Description

Intelligent regulation and control system for photovoltaic inverter

Technical Field

The application relates to the technical field of photovoltaics, in particular to an intelligent regulation and control system of a photovoltaic inverter.

Background

The photovoltaic power generation system mainly comprises a solar panel assembly (PV assembly), a controller and an inverter. Currently, in a photovoltaic unit (or called a photovoltaic system for a user), an energy storage battery is configured in addition to the above modules to store electric energy generated by a PV module, and energy scheduling is realized through the energy storage battery at night or when the illumination intensity is reduced. The inverter has a grid-connected mode and an off-grid mode, and when the inverter is connected, energy can be transmitted to a power grid, and electricity can be taken from the power grid.

The technical staff research finds that: the inverter of the photovoltaic units of the plurality of households is easy to cause voltage fluctuation of the power grid due to electricity taking and discharging from the power grid, and a technology for reasonably scheduling energy among the photovoltaic units of the plurality of households is lacking at present so as to solve the technical problems.

Disclosure of Invention

In order to at least partially realize the technical aim, the application provides an intelligent regulation and control system for a photovoltaic inverter.

The intelligent regulation and control system of the photovoltaic inverter provided by the application adopts the following technical scheme.

The intelligent regulation and control system for the photovoltaic inverter is characterized by comprising a plurality of photovoltaic units for households;

Each of the household photovoltaic units comprises:

a photovoltaic inverter; the grid-connected port of the photovoltaic inverter is connected with a power grid;

A PV assembly connected to a PV port of the photovoltaic inverter;

The energy storage battery is electrically connected with the photovoltaic inverter;

an electrical load; the power utilization load is connected with the photovoltaic inverter;

The photovoltaic inverters of the household photovoltaic units are electrically connected with the photovoltaic inverters of the adjacent household photovoltaic units through power lines;

Each household photovoltaic unit performs electric energy self-use or performs electricity taking or discharging to the adjacent household photovoltaic units according to the power generation pre-measurement of the PV component, the storage electric quantity of the energy storage battery and the total electric quantity of the electricity utilization load; and under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the electricity is taken or discharged to the power grid.

By adopting the technical scheme, the electric energy interaction between the photovoltaic units of the user is preferentially carried out, the probability of electricity taking or discharging to the power grid is reduced, and further the fluctuation of the power grid is reduced.

Optionally, each household photovoltaic unit performs electric energy self-use or performs electricity taking or discharging to the adjacent household photovoltaic units according to the power generation pre-measurement of the PV assembly, the storage electric quantity of the energy storage battery and the total electric quantity of the electricity utilization load; under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the method for taking or discharging the electricity to the power grid comprises the following steps:

acquiring the electric quantity stored by the energy storage battery in the photovoltaic unit of the household, and recording the electric quantity as the stored electric quantity;

Acquiring weather forecast data and inputting the weather forecast data into a photovoltaic prediction model to obtain a power generation predicted quantity;

acquiring the electricity consumption of an electricity consumption load in the current time period, and recording the electricity consumption as first electricity consumption; predicting the electricity consumption of the next stage based on the first electricity consumption, and recording the electricity consumption as second electricity consumption; and

Judging whether electric energy is used by itself or not based on the stored electric quantity, the power generation predicted quantity and the second electric quantity, and taking or discharging electricity to a photovoltaic unit of an adjacent user; and under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the electricity is taken or discharged to the power grid.

Optionally, based on the stored electricity quantity, the power generation predicted quantity and the second electricity consumption quantity, judging whether the electric energy is used by itself, and taking or discharging electricity to the photovoltaic units of adjacent users; under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the method for taking or discharging the electricity to the power grid comprises the following steps:

Judging whether an electric energy self-use condition is met or not based on the stored electric quantity, the power generation predicted quantity and the second electric quantity; if yes, carrying out electric energy self-use;

If the electric energy self-use condition is judged not to be met, judging whether redundant electric energy is transmitted to the photovoltaic units of the adjacent users; if yes, judging whether the adjacent household photovoltaic units need to be powered;

If the fact that the adjacent household photovoltaic units need to be powered on is judged, the photovoltaic inverter is controlled to discharge to the household photovoltaic units needing to be powered on; and

And if no adjacent household photovoltaic units need to be powered, controlling the photovoltaic inverter to discharge to a power grid.

Optionally, when N adjacent household photovoltaic units need to get electricity, the photovoltaic inverter is controlled to discharge electricity to the household photovoltaic units needing to get electricity, including:

obtaining an allocable electric quantity M based on the stored electric quantity, the power generation predicted quantity and the second electric quantity;

initializing a storage list;

sequencing according to the number of electric quantity required by all household photovoltaic units from large to small;

Starting from the maximum required electric quantity, sequentially distributing the distributable electric quantity M to each household photovoltaic unit; if the current residual electric quantity is insufficient to meet the requirement of the photovoltaic unit of one user, skipping the photovoltaic unit of the user, and continuing to distribute the photovoltaic unit to the next user until the distributable electric quantity M is completely distributed or until the residual electric quantity of the distributable electric quantity M is smaller than a preset value; during the distribution process, the distributed household photovoltaic units are recorded in a storage list;

discharging to the user photovoltaic units in the storage list.

Optionally, the training method of the photovoltaic prediction model includes:

Constructing an initial prediction neural network based on parameter information of a PV component of a photovoltaic unit of a user;

training the initial prediction neural network by adopting historical photovoltaic power generation data to obtain an initial prediction model;

obtaining a power generation predicted value according to the initial prediction model prediction, and obtaining a power generation actual value of a photovoltaic unit of a user;

And carrying out confidence verification on the initial prediction model based on the power generation actual value, and obtaining a photovoltaic prediction model when the confidence meets a preset value.

Optionally, the electric load comprises a charging pile and a household appliance.

Drawings

FIG. 1 is a system block diagram of a photovoltaic inverter intelligent regulation system in accordance with an embodiment of the present application;

In the figure, 101, a photovoltaic inverter; 102. a PV assembly; 103. an energy storage battery; 104. and (5) using an electric load.

Detailed Description

The application is further illustrated by the following description of the specific embodiments in conjunction with the accompanying drawings of fig. 1:

First, what needs to be described here is: in the description of the present application, terms such as "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," "outer," and the like are used for convenience of description only as regards orientation or positional relationship as shown in the accompanying drawings, and do not denote or imply that the apparatus or element in question must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present application; moreover, the numerical terms such as the terms "first," "second," "third," etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In addition, unless explicitly stated or limited otherwise, the terms "mounted," "connected," and "connected" should be construed broadly, and may be, for example, a fixed connection, a releasable connection, an interference fit, a transition fit, or an integral connection; can be directly connected or indirectly connected through an intermediate medium; the specific meaning of the above terms in the present application will be understood by those skilled in the art according to the specific circumstances.

The embodiment of the application discloses an intelligent regulation and control system for a photovoltaic inverter 101. Referring to fig. 1, as an embodiment of a photovoltaic inverter 101 intelligent regulation system, a photovoltaic inverter 101 intelligent regulation system includes a plurality of photovoltaic units for a household;

each of the household photovoltaic units comprises: photovoltaic inverter 101, PV module 102, energy storage cell 103, and electrical load 104.

The grid connection port of the photovoltaic inverter 101 is connected with a power grid. In particular, the photovoltaic inverter 101 is a power electronics device whose primary function is to convert direct current generated by a photovoltaic module (PV module 102) into alternating current for incorporation into the grid or for use by a consumer. The grid-connected port of the photovoltaic inverter 101 is connected with a power grid, and the photovoltaic inverter 101 can directly inject generated alternating current into the power grid to realize grid-connected operation of a photovoltaic power generation system or take power from the power grid.

The PV assembly 102 is connected to the PV port of the photovoltaic inverter 101. The PV module 102, also known as a photovoltaic module, is an important component in a photovoltaic system. The solar cell mainly comprises a plurality of solar cells, and absorbs sunlight and converts the sunlight into electric energy. When sunlight impinges on the PV assembly 102, the solar cells in the PV assembly 102 convert light energy to electrical energy and output as direct current. The direct current is transmitted to the PV port of the photovoltaic inverter 101 through the connection line, and then the photovoltaic inverter 101 performs current conversion and frequency adjustment, and finally outputs as stable and usable alternating current.

The energy storage battery 103 is electrically connected to the photovoltaic inverter 101. The energy storage cell 103 is typically composed of a plurality of battery cells, converts electrical energy into chemical energy for storage by electrochemical reaction, and converts chemical energy into electrical energy for output by reverse reaction when needed. The electrical connection between the energy storage battery 103 and the photovoltaic inverter 101 means that the electrical connection is established between the energy storage battery 103 and the photovoltaic inverter 101, so as to realize energy transmission and conversion, and the electric energy generated by the photovoltaic power generation system is converted into alternating current electric energy through the photovoltaic inverter 101, and then is transmitted to the energy storage battery 103 for storage through the electrical connection. When power is required, the energy storage battery 103 may provide the required dc power to the photovoltaic inverter 101.

The power load 104 is connected to the photovoltaic inverter 101. Specifically, the electrical load 104 refers to a device or system capable of consuming electrical energy, such as a light bulb, an air conditioner, a television, or the like. The connection between the electric load 104 and the photovoltaic inverter 101 requires that the direct current generated by the photovoltaic power generation system is converted by the photovoltaic inverter 101 to be supplied to the electric load 104.

The photovoltaic inverters 101 of the household photovoltaic units are electrically connected with the photovoltaic inverters 101 of the adjacent household photovoltaic units through power lines; each household photovoltaic unit performs electric energy self-use or performs electricity taking or discharging to the adjacent household photovoltaic units according to the power generation pre-measurement of the PV component 102, the storage electric quantity of the energy storage battery 103 and the total electric quantity of the electricity utilization load 104; and under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the electricity is taken or discharged to the power grid. Specifically, the photovoltaic inverter 101 of the photovoltaic unit of the household is electrically connected to the photovoltaic inverter 101 of the photovoltaic unit of the adjacent household through a power line, and each photovoltaic unit of the household is regulated and controlled according to the total power generation amount, the stored power of the energy storage battery 103 and the total power consumption amount. When the predicted amount of power generation by the photovoltaic module 102 exceeds the user's demand, the system automatically stores excess electrical energy into the energy storage cell 103 or delivers it to an adjacent household photovoltaic unit. When the power of the energy storage battery 103 is insufficient or the user needs more power, the system can take or discharge power from the power grid or other photovoltaic units for user to meet the power demand of the user. Because the electric energy interaction between the photovoltaic units of the user is preferentially carried out, the probability of electricity taking or discharging to the power grid is reduced, and further fluctuation of the power grid is reduced.

As a specific implementation mode of the intelligent regulation and control system of the photovoltaic inverter 101, each household photovoltaic unit performs electric energy self-use or performs electricity taking or discharging to the adjacent household photovoltaic units according to the power generation predicted quantity of the PV assembly 102, the stored electric quantity of the energy storage battery 103 and the total electric quantity of the electric load 104; under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the method for taking or discharging the electricity to the power grid comprises the following steps:

acquiring the electric quantity stored by the energy storage battery 103 in the photovoltaic unit of the user, and recording the electric quantity as the stored electric quantity;

Acquiring weather forecast data and inputting the weather forecast data into a photovoltaic prediction model to obtain a power generation predicted quantity;

acquiring the electricity consumption of the electricity load 104 in the current time period, and recording the electricity consumption as first electricity consumption; predicting the electricity consumption of the next stage based on the first electricity consumption, and recording the electricity consumption as second electricity consumption; and

Judging whether electric energy is used by itself or not based on the stored electric quantity, the power generation predicted quantity and the second electric quantity, and taking or discharging electricity to a photovoltaic unit of an adjacent user; and under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the electricity is taken or discharged to the power grid.

Specifically, the electric quantity stored in the energy storage battery 103 in the photovoltaic unit for the user is obtained, weather forecast data is obtained and is input into the photovoltaic prediction model, so that a power generation predicted quantity is obtained; the electricity consumption of the electricity load 104 in the current time period is obtained and is recorded as a first electricity consumption, and the electricity consumption of the next stage is predicted based on the first electricity consumption and is recorded as a second electricity consumption. Judging whether electricity needs to be taken or discharged to a photovoltaic unit or a power grid of an adjacent household or not based on the stored electricity quantity, the electricity generation predicted quantity and the second electricity consumption quantity; and under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the electricity is taken or discharged to the power grid. If the stored electricity is insufficient to meet the demand, or the power generation prediction amount is low, the photovoltaic unit is preferentially used for acquiring the electric energy from other users. If the stored electricity is sufficient and the predicted amount of power generation is high, the excess electric energy is preferentially released to the photovoltaic units of other users.

As a specific implementation mode of the intelligent regulation and control system of the photovoltaic inverter 101, judging whether electric energy is used by itself or not based on the stored electric quantity, the power generation predicted quantity and the second electric quantity, and taking or discharging electricity to a photovoltaic unit of an adjacent household; under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the method for taking or discharging the electricity to the power grid comprises the following steps:

Judging whether an electric energy self-use condition is met or not based on the stored electric quantity, the power generation predicted quantity and the second electric quantity; if yes, carrying out electric energy self-use;

If the electric energy self-use condition is judged not to be met, judging whether redundant electric energy is transmitted to the photovoltaic units of the adjacent users; if yes, judging whether the adjacent household photovoltaic units need to be powered;

If it is determined that the photovoltaic units of the adjacent households need to be powered, the photovoltaic inverter 101 is controlled to discharge to the photovoltaic units of the households needing to be powered; and

And if no adjacent household photovoltaic units need to be powered, controlling the photovoltaic inverter 101 to discharge to a power grid.

As a specific implementation mode of the intelligent regulation system of the photovoltaic inverter 101, if no redundant electric energy is judged to discharge to the photovoltaic units of the adjacent households, judging whether the adjacent household photovoltaic units can be powered;

if so, electricity is taken from the photovoltaic units of the adjacent users;

If not, electricity is taken from the power grid.

As one implementation manner of the intelligent regulation system of the photovoltaic inverter 101, when N adjacent household photovoltaic units need to be powered, the photovoltaic inverter 101 is controlled to discharge electricity to the household photovoltaic units needing to be powered, including:

obtaining an allocable electric quantity M based on the stored electric quantity, the power generation predicted quantity and the second electric quantity;

initializing a storage list;

sequencing according to the number of electric quantity required by all household photovoltaic units from large to small;

starting from the maximum required electric quantity, sequentially distributing the distributable electric quantity M to each household photovoltaic unit; if the current residual electric quantity is insufficient to meet the requirement of the photovoltaic unit of one user, skipping the photovoltaic unit of the user, and continuing to distribute the photovoltaic unit to the next user until the distributable electric quantity M is completely distributed or until the residual electric quantity of the distributable electric quantity M is smaller than a preset value; during the distribution process, the distributed household photovoltaic units are recorded in a storage list.

Specifically, the number of the photovoltaic unit or the equipment information of the user or the electric quantity required to be transmitted is recorded in the storage list. The electricity can be quickly searched and distributed by obtaining the distributable electricity M based on the stored electricity, the electricity generation predicted quantity and the second electricity consumption and initializing a storage list for storing the photovoltaic units of the households which are already distributed with the electricity; the electric energy is sorted from large to small according to the electric quantity number required by all household photovoltaic units, so that the electric energy can be ensured to be firstly distributed to the household photovoltaic units with large demand; starting from the maximum required power quantity, the allocatable power quantity M is allocated to each household photovoltaic unit in turn. If the current residual electric quantity is insufficient to meet the requirement of the photovoltaic unit of one user, skipping the photovoltaic unit of the user, and continuing to distribute the photovoltaic unit to the next user until the distributable electric quantity M is completely distributed or until the residual electric quantity of the distributable electric quantity M is smaller than a preset value; during the distribution process, the distributed household photovoltaic units are recorded in a storage list. The distribution times of the distributable electric quantity M are reduced, and further the electric energy fluctuation between the power grid or the photovoltaic units of the household is reduced.

As one embodiment of the intelligent regulation system of the photovoltaic inverter 101, the training method of the photovoltaic prediction model includes:

Constructing an initial predictive neural network based on parameter information of the PV assemblies 102 of the user's photovoltaic units;

training the initial prediction neural network by adopting historical photovoltaic power generation data to obtain an initial prediction model;

obtaining a power generation predicted value according to the initial prediction model prediction, and obtaining a power generation actual value of a photovoltaic unit of a user;

And carrying out confidence verification on the initial prediction model based on the power generation actual value, and obtaining a photovoltaic prediction model when the confidence meets a preset value.

Specifically, an initial prediction neural network is constructed based on parameter information of the PV module 102 of the photovoltaic unit of the user, the initial prediction neural network is trained by using historical photovoltaic power generation data, an initial prediction model is obtained, and the prediction model is established through a machine learning algorithm. And the power generation predicted value is obtained according to the prediction of the initial predicted model, the power generation actual value of the photovoltaic unit of the user is obtained, the confidence verification is carried out on the initial predicted model based on the power generation actual value, the accuracy and the reliability of the predicted model are improved by the photovoltaic predicted model when the confidence degree meets the preset value, and the predicted model is higher in accuracy and reliability when the confidence degree meets the preset value.

As one implementation mode of the intelligent regulation system of the photovoltaic inverter 101, the electric load 104 includes a charging pile and a household appliance.

It should be noted that: although the present application has been described in detail with reference to the above embodiments, it should be understood by those skilled in the art that the present application may be modified or equivalent thereto without departing from the spirit and scope of the application, and all such modifications and improvements thereof are intended to be included within the scope of the appended claims.

Claims (3)

1. The intelligent regulation and control system for the photovoltaic inverter is characterized by comprising a plurality of photovoltaic units for households;

Each of the household photovoltaic units comprises:

a photovoltaic inverter; the grid-connected port of the photovoltaic inverter is connected with a power grid;

A PV assembly connected to a PV port of the photovoltaic inverter;

The energy storage battery is electrically connected with the photovoltaic inverter;

an electrical load; the power utilization load is connected with the photovoltaic inverter;

The photovoltaic inverters of the household photovoltaic units are electrically connected with the photovoltaic inverters of the adjacent household photovoltaic units through power lines;

Each household photovoltaic unit performs electric energy self-use or performs electricity taking or discharging to the adjacent household photovoltaic units according to the power generation pre-measurement of the PV component, the storage electric quantity of the energy storage battery and the total electric quantity of the electricity utilization load; under the condition that the self-use of electric energy is not met and the electricity is taken or discharged to the adjacent household photovoltaic units, the electricity is taken or discharged to the power grid;

Each household photovoltaic unit performs electric energy self-use or performs electricity taking or discharging to the adjacent household photovoltaic units according to the power generation pre-measurement of the PV component, the storage electric quantity of the energy storage battery and the total electric quantity of the electricity utilization load; under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the method for taking or discharging the electricity to the power grid comprises the following steps:

acquiring the electric quantity stored by the energy storage battery in the photovoltaic unit of the household, and recording the electric quantity as the stored electric quantity;

Acquiring weather forecast data and inputting the weather forecast data into a photovoltaic prediction model to obtain a power generation predicted quantity;

acquiring the electricity consumption of an electricity consumption load in the current time period, and recording the electricity consumption as first electricity consumption; predicting the electricity consumption of the next stage based on the first electricity consumption, and recording the electricity consumption as second electricity consumption; and

Judging whether electric energy is used by itself or not based on the stored electric quantity, the power generation predicted quantity and the second electric quantity, and taking or discharging electricity to a photovoltaic unit of an adjacent user; under the condition that the self-use of electric energy is not met and the electricity is taken or discharged to the adjacent household photovoltaic units, the electricity is taken or discharged to the power grid;

Judging whether electric energy is used by itself or not based on the stored electric quantity, the power generation predicted quantity and the second electric quantity, and taking or discharging electricity to a photovoltaic unit of an adjacent user; under the condition that the self-use of electric energy is not satisfied and the electricity is taken or discharged to the adjacent household photovoltaic units, the method for taking or discharging the electricity to the power grid comprises the following steps:

Judging whether an electric energy self-use condition is met or not based on the stored electric quantity, the power generation predicted quantity and the second electric quantity; if yes, carrying out electric energy self-use;

If the electric energy self-use condition is judged not to be met, judging whether redundant electric energy is transmitted to the photovoltaic units of the adjacent users; if yes, judging whether the adjacent household photovoltaic units need to be powered;

If the fact that the adjacent household photovoltaic units need to be powered on is judged, the photovoltaic inverter is controlled to discharge to the household photovoltaic units needing to be powered on; and

If no adjacent household photovoltaic units need to be powered, the photovoltaic inverter is controlled to discharge to a power grid;

if no redundant electric energy is judged to discharge to the adjacent household photovoltaic units, judging whether the adjacent household photovoltaic units can be powered;

if so, electricity is taken from the adjacent household photovoltaic units;

If the power is not available, taking power from the power grid;

When N adjacent household photovoltaic units need to be powered, the photovoltaic inverter is controlled to discharge electricity to the household photovoltaic units needing to be powered, and the method comprises the following steps:

obtaining an allocable electric quantity M based on the stored electric quantity, the power generation predicted quantity and the second electric quantity;

initializing a storage list;

sequencing according to the number of electric quantity required by all household photovoltaic units from large to small;

Starting from the maximum required electric quantity, sequentially distributing the distributable electric quantity M to each household photovoltaic unit; if the current residual electric quantity is insufficient to meet the requirement of the photovoltaic unit of one user, skipping the photovoltaic unit of the user, and continuing to distribute the photovoltaic unit to the next user until the distributable electric quantity M is completely distributed or until the residual electric quantity of the distributable electric quantity M is smaller than a preset value; during the distribution process, the distributed household photovoltaic units are recorded in a storage list;

discharging to the user photovoltaic units in the storage list.

2. The intelligent regulation and control system of a photovoltaic inverter according to claim 1, wherein the training method of the photovoltaic prediction model comprises:

Constructing an initial prediction neural network based on parameter information of a PV component of a photovoltaic unit of a user;

training the initial prediction neural network by adopting historical photovoltaic power generation data to obtain an initial prediction model;

obtaining a power generation predicted value according to the initial prediction model prediction, and obtaining a power generation actual value of a photovoltaic unit of a user;

And carrying out confidence verification on the initial prediction model based on the power generation actual value, and obtaining a photovoltaic prediction model when the confidence meets a preset value.

3. The intelligent regulation and control system of a photovoltaic inverter according to claim 2, wherein the power load comprises a charging pile and a household appliance.