BE1031378B1 - Procedure and system for managing the operation and maintenance of photovoltaic systems - Google Patents

Abstract

The present invention relates to the technical field of photovoltaic power plants, in particular to a method and system for managing the operation and maintenance of photovoltaic systems, the method comprising the steps of: collecting operating data of a photovoltaic power plant; constructing a control model of the photovoltaic power plant based on the constraints of the photovoltaic power plant and ensuring system stability under extreme weather conditions as an objective function, and optimizing and solving the control model of the photovoltaic power plant by a solver, and outputting the optimized control model of the photovoltaic power plant after the test; inputting real-time operating data of the photovoltaic power plant and weather data to the optimized control model of the photovoltaic power plant to calculate and obtain an optimal control strategy for the photovoltaic power plant.

Description

Procedure and system for managing the operation and maintenance of

Photovoltaic systems

TECHNICAL FIELD

The present invention relates to the technical field of photovoltaic power plants, in particular to a method and system for managing the operation and maintenance of

Photovoltaic systems.

STATE OF THE ART

The problems faced by power systems during extreme thunderstorms have attracted increasing attention worldwide.

Currently, the existing control methods for photovoltaic power plants that have to withstand extreme weather conditions are mainly based on the objective of

Profit maximization. However, under extreme weather conditions, photovoltaic power plants are susceptible to greater stress and losses. The sole pursuit of

Profit maximization not only neglects the health and service life of photovoltaic power plants, but also leads to damage and premature shutdown of the plants as well as to higher costs for repair and

replacement of the equipment. This also easily leads to potential safety accidents and

losses in photovoltaic power plants. Based on this, a procedure and system for managing the operation and

Maintenance of photovoltaic systems.

CONTENT OF THE PRESENT INVENTION

One purpose of the present invention is to provide a method and system for

Management of the operation and maintenance of photovoltaic systems, which, with the arrangement of a control model of the photovoltaic power plant with the aim of ensuring system stability under extreme weather conditions, not only a more efficient operation of the photovoltaic power plant under extreme

weather conditions, reducing energy waste and emissions, but also improving the stability and profit of the photovoltaic power plant, reducing losses and maintenance costs.

An embodiment of the present invention is illustrated by the following technical

Solution implemented: a procedure for managing the operation and maintenance of photovoltaic systems, comprising the following steps:

Collecting operating data from a photovoltaic power plant;

Constructing a control model of the photovoltaic power plant based on the

Constraints of the photovoltaic power plant and ensuring system stability under extreme weather conditions as an objective function, and optimizing and solving the

control model of the photovoltaic power plant by a solver, and outputting the optimized control model of the photovoltaic power plant after the test;

Inputting real-time operating data of the photovoltaic power plant and weather data into the optimized control model of the photovoltaic power plant to calculate and obtain an optimal control strategy for the photovoltaic power plant.

Optionally, the operating data of the photovoltaic power plant includes: Data on

Solar radiation, performance data of power plant components, historical data on extreme weather events and data on electricity market prices.

Optionally, the procedure includes collecting the operating data of the photovoltaic

Power plant also includes a data preprocessing step to clean and standardize the operating data of the photovoltaic power plant.

Optionally, the constraints of the photovoltaic power plant include: a power balancing constraint, an operation limitation constraint for the equipment, and a capacity limitation constraint for the energy storage equipment; where the power balancing constraint is calculated by the following formula: e + d, = } + c, VteT where e, the power generation amount at time t, d, the discharge amount of the

Energy storage system at time t, / the load demand at time t, c, the

Charging quantity of the energy storage system at time t and T the total number of

time periods; and where the operating limitation constraint for the equipment is as follows: < < €, S Erax , OSC, S Conax , 0< d, < Dax and where E… is the maximum power generation capacity of the photovoltaic power plant,

Ca is the maximum charging capacity of the energy storage system and D… is the maximum

Discharge capacity of the energy storage system; and wherein the capacity limitation restriction for the energy storage equipment is as follows:

S vain < 5, < Snax and where s, is the stored energy in the energy storage system at time t, and where Sum vod SA are the minimum and maximum capacity of the

energy storage system.

Optionally, ensuring system stability under extreme weather conditions is used as an objective function, with the calculation formula being as follows:

T n=max > (a-R-B-C-y:F) =] where T is the total number of time periods, R is the reliability of the system, C is the

operating costs, F is the cost of failures or losses due to

system instability, and a, B, y are weighting coefficients to balance the relative importance of each factor in the objective function.

Optionally, in the step of optimizing and solving the control model of the

Photovoltaic power plant by a solver, in particular a CPLEX solver or a Gurobi solver.

A system for managing the operation and maintenance of photovoltaic systems, comprising: a collection unit for collecting operating data of a photovoltaic power plant; a design unit for constructing a control model of the photovoltaic

power plant based on the limitations of the photovoltaic power plant and the

Ensuring system stability under extreme weather conditions as a target function,

Optimizing and solving the control model of the photovoltaic power plant by a

Solver, and outputting the optimized control model of the photovoltaic power plant after the test; and an execution unit for inputting real-time operating data of the photovoltaic

Power plant and weather data into the optimized control model of the photovoltaic

power plant to calculate and obtain an optimal control strategy for the

Photovoltaic power plant.

The technical solution of the embodiment of the present invention has the following advantages and advantageous effects: with the arrangement of a control model of the photovoltaic power plant with the aim of

To ensure system stability under extreme weather conditions, the

embodiment of the present invention not only enables more efficient operation of the

photovoltaic power plant under extreme weather conditions, which

Energy waste and emissions are reduced, but also improves the

stability and profit of the photovoltaic power plant, thereby reducing the losses and

Maintenance costs can be reduced.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 shows a flowchart of one of an embodiment of the present

The method provided by the invention for managing the operation and maintenance of

Photovoltaic systems.

DETAILED DESCRIPTION

In conjunction with the accompanying drawings in the embodiments of the present invention, the technical solution in the embodiments of the present invention will be explained clearly and completely below, so that the object, technical solutions and advantages of the present invention will become clearer.

Obviously, the described examples do not represent all

embodiments, but only a part of the embodiments of the present

invention. The invention explained and illustrated in the accompanying drawings

Components of embodiments of the present invention can typically be arranged and designed in various configurations.

As shown in Figure 1, the present invention provides an embodiment for

a procedure for managing the operation and maintenance of

Photovoltaic systems, comprising the following steps:

Collecting operating data from a photovoltaic power plant;

Constructing a control model of the photovoltaic power plant based on the

Constraints of the photovoltaic power plant and ensuring system stability under extreme weather conditions as an objective function, and optimizing and solving the

control model of the photovoltaic power plant by a solver, and outputting the optimized control model of the photovoltaic power plant after the test;

Inputting real-time operating data of the photovoltaic power plant and weather data into the optimized control model of the photovoltaic power plant to calculate and obtain an optimal control strategy for the photovoltaic power plant.

In the present embodiment, the present embodiment collects the operating data of the photovoltaic system through the sensors and monitoring devices.

power plant, creates a mathematical model based on the constraints of the

Photovoltaic power plant and the objective function to determine the operating characteristics and

To describe the control requirements of the photovoltaic power plant, optimizes and solves the constructed control model of the photovoltaic power plant using a solver to obtain the optimal control strategy and outputs the real-time operating data of the

photovoltaic power plant and the weather data into the optimized control model in order to obtain an optimal control strategy for the photovoltaic power plant through the calculation. The application of the present embodiment not only enables the

Monitoring and control of the photovoltaic power plant in real time, improves the

operational efficiency and stability, but also enables more efficient operation of the

photovoltaic power plant under extreme weather conditions and reduces the

Energy waste and emissions.

In particular, the operating data of the photovoltaic power plant include: Data on

Solar radiation, performance data of power plant components, historical data on extreme weather events and data on electricity market prices.

More specifically, after collecting the operational data of the

Photovoltaic power plant also includes a data preprocessing step to clean and standardize the operating data of the photovoltaic power plant.

In the present embodiment, the limitations of the photovoltaic

power plant: a restriction of the power balance, a restriction of the

Operation limitation for the equipment and a capacity limitation limitation for the energy storage equipment; the power balancing limitation is calculated by the following formula: e + d, = } + c, VteT where e, the power generation amount at time t, d, the discharge amount of the

Energy storage system at time t, / the load demand at time t, c, the

Charging quantity of the energy storage system at time t and T the total number of

time periods; and where the restriction of the operating limitation for the equipment is as follows:

É, S Ennax , 0<c, S Conax , 0< d, < Dax and where E… is the maximum power generation capacity of the photovoltaic power plant,

Ca is the maximum charging capacity of the energy storage system and D, the maximum

Discharge capacity of the energy storage system; and wherein the capacity limitation for the energy storage equipment 5 is as follows:

Sin ss t Ss Snax and where s is the stored energy in the energy storage system at time t, and where Sn and 8 are the minimum and maximum capacity of the

energy storage system.

Furthermore, ensuring system stability under extreme weather conditions is considered

objective function is used, where the calculation formula is as follows:

T n=max > (0-R-B-C_y.F) =] where T is the total number of time periods, R is the reliability of the system, C is the

operating costs, F is the cost of failures or losses due to

system instability, and a, B, y are weighting coefficients to balance the relative importance of each factor in the objective function.

More specifically, in the step of optimizing and solving the control model of the

Photovoltaic power plant by a solver, the solver takes in particular a CPLEX

Solver or a Gurobi solver.

The present invention further provides another embodiment, a system for managing the operation and maintenance of photovoltaic systems, comprising: a collection unit for collecting operation data of a photovoltaic power plant; a design unit for designing a control model of the photovoltaic

power plant based on the limitations of the photovoltaic power plant and the

Ensuring system stability under extreme weather conditions as a target function,

Optimizing and solving the control model of the photovoltaic power plant by a

Solver, and outputting the optimized control model of the photovoltaic power plant after the test; and an execution unit for inputting real-time operating data of the photovoltaic

Power plant and weather data into the optimized control model of the photovoltaic

power plant to calculate and obtain an optimal control strategy for the

Photovoltaic power plant.

The system provided by the present embodiment for managing the

Operation and maintenance of photovoltaic systems has the same inventive concept as the method provided by the above embodiment for managing the

Operation and maintenance of photovoltaic systems, and for the more specific working principle of the respective modules in the embodiment of the present invention, reference is made to the above embodiment, which is not repeated in the embodiment of the present invention.

The above content represents only preferred embodiments of the present

invention and is not intended to limit the present invention. The

Those skilled in the art may make various changes and modifications to the present invention. All within the spirit and principles of the present

/ BE2024/5396

Any changes, equivalent substitutions, and improvements made to the invention should be deemed to be within the scope of the present invention.

Claims (7)

Claims 1. A method for managing the operation and maintenance of photovoltaic systems, characterized in that it comprises the following steps: collecting operating data of a photovoltaic power plant; constructing a control model of the photovoltaic power plant based on the constraints of the photovoltaic power plant and ensuring system stability under extreme weather conditions as the objective function, and optimizing and solving the control model of the photovoltaic power plant through a solver, and outputting the optimized control model of the photovoltaic power plant after the test; inputting real-time operating data of the photovoltaic power plant and weather data into the optimized control model of the photovoltaic power plant to calculate and obtain an optimal control strategy for the photovoltaic power plant. 2. A method for managing the operation and maintenance of photovoltaic systems according to claim 1, characterized in that the operating data of the photovoltaic power plant include solar radiation data, power plant component performance data, historical data on extreme weather events, and electricity market price data. 3. A method for managing the operation and maintenance of photovoltaic systems according to claim 2, characterized in that the method, after collecting the operating data of the photovoltaic power plant, further comprises a data preprocessing step for cleaning and standardizing the operating data of the photovoltaic power plant. 4. A method for managing the operation and maintenance of photovoltaic systems according to claim 1, characterized in that the constraints of the photovoltaic power plant include a power balancing constraint, an operation limitation constraint for the equipment, and a capacity limitation constraint for the energy storage equipment; wherein the power balancing constraint is calculated by the following formula: e‚+d, =l, +c, VteT where e is the power generation amount at time t, d is the discharge amount of the energy storage system at time t, / the load demand at time t, c‚ is the charge amount of the energy storage system at time t, and T is the total number of time periods; and wherein the operation limitation constraint for the equipment is as follows: < < €, S Emax, 0<c, < Coax 0 Sd, < Donax and where E… is the maximum power generation capacity of the photovoltaic power plant, Ca is the maximum charge capacity of the energy storage system, and D… is the maximum discharge capacity of the energy storage system; and wherein the capacity limit constraint for the energy storage equipment is as follows: Sin Ss 5, Ss Snax and where s, is the stored energy in the energy storage system at time t, and where Sum vod 8 are the minimum and maximum capacities of the energy storage system, respectively. 5. A method for managing the operation and maintenance of photovoltaic systems according to claim 4, characterized in that ensuring system stability under extreme weather conditions is used as the objective function, the calculation formula being as follows: T n=max > (0-R-B-C-y.F) =] where T is the total number of time periods, R is the reliability of the system, C is the operating cost, F is the cost of failures or losses due to system instability, and a, B, y are each weighting coefficients to compensate for the relative importance of each factor in the objective function. 6. A method for managing the operation and maintenance of photovoltaic systems according to claim 1, characterized in that in the step of optimizing and solving the control model of the photovoltaic power plant by a solver, the solver adopts in particular a CPLEX solver or a Gurobi solver. 7. A system for managing the operation and maintenance of photovoltaic systems, characterized in that it comprises: a collection unit for collecting operating data of a photovoltaic power plant; a design unit for constructing a control model of the photovoltaic power plant based on the constraints of the photovoltaic power plant and ensuring system stability under extreme weather conditions as the objective function, optimizing and solving the control model of the photovoltaic power plant through a solver, and outputting the optimized control model of the photovoltaic power plant after the test; and an execution unit for inputting real-time operating data of the photovoltaic power plant and weather data into the optimized control model of the photovoltaic power plant to calculate and obtain an optimal control strategy for the photovoltaic power plant.