CN111969950A - Photovoltaic power supply system operation state detection method and device and terminal - Google Patents

Abstract

The invention provides a method, a device and a terminal for detecting the running state of a photovoltaic power supply system, wherein the method comprises the following steps: acquiring operating parameters corresponding to a photovoltaic power supply system and a time node, wherein the operating parameters at least comprise ambient temperature, voltage and current; constructing the operation parameters corresponding to the time nodes into an operation parameter set by taking the time nodes as labels; selecting the operation parameter set with the environment temperature as a preset temperature as a sample comparison unit; comparing the operating parameters of the sample comparison unit with standard values; and obtaining the operating state of the photovoltaic power supply system according to the comparison result of the operating parameters and the standard values of the sample comparison unit. The invention changes the passive mode of examining and determining the cause one by one into the active positioning problem cause, improves the maintenance and repair efficiency and reduces the maintenance cost.

Description

Photovoltaic power supply system operation state detection method and device and terminal

Technical Field

The invention relates to the field of photovoltaics, in particular to a method, a device and a terminal for detecting the running state of a photovoltaic power supply system.

Background

The photovoltaic power supply system is a system at the core of the photovoltaic system, the common maintenance problems of the existing photovoltaic power supply system mainly comprise that the effective capacity of a storage battery is insufficient, the power consumption of a load is not matched with the power generation and standby power capacities, the charging current is set to be too large or too small, the photovoltaic power generation system is low in efficiency, the performance of the standby power system (the storage battery) is deteriorated, and the like. At present, common maintenance modes and fault diagnosis modes are all that maintenance personnel are all carried out passively and blindly, once a fault occurs, the fault is required to be checked, confirmed and eliminated one by one, the fault removal efficiency is low, the state and the fault of the photovoltaic power supply system cannot be quickly and effectively detected, the maintenance cost is greatly improved, the normal production of the photovoltaic system is influenced, and the working efficiency of the photovoltaic power supply system is reduced.

Disclosure of Invention

The embodiment of the invention aims to provide a method, a device and a terminal for detecting the running state of a photovoltaic power supply system, and aims to provide a method for quickly and accurately determining the running state of the photovoltaic power supply system and determining the fault reason.

In order to achieve the above object, a first aspect of the embodiments of the present invention provides a method for detecting an operating state of a photovoltaic power supply system, including:

acquiring operating parameters corresponding to a photovoltaic power supply system and a time node, wherein the operating parameters at least comprise ambient temperature, voltage and current;

constructing the operation parameters corresponding to the time nodes into an operation parameter set by taking the time nodes as labels;

selecting the operation parameter set with the environment temperature as a preset temperature as a sample comparison unit;

comparing the operating parameters of the sample comparison unit with standard values;

and obtaining the operating state of the photovoltaic power supply system according to the comparison result of the operating parameters and the standard values of the sample comparison unit.

Optionally, the selecting the operating parameter set with the environmental temperature being a preset temperature as a sample comparison unit includes:

dividing the parameter set into a plurality of temperature groups according to the ambient temperature in the parameter set;

and selecting the temperature group with the environment temperature as a preset temperature as a sample comparison unit.

Optionally, the dividing the parameter set into a plurality of temperature groups according to the ambient temperature in the parameter set includes:

and replacing all the ambient temperatures in each temperature group by the same temperature label, wherein the temperature labels of different temperature groups are different.

Optionally, before the selecting the operating parameter set with the environmental temperature being a preset temperature as a sample comparison unit, the method further includes:

and taking a time-continuous operation parameter set as sample units, wherein each sample unit comprises a charging operation parameter subunit and a discharging operation parameter subunit.

Optionally, the selecting the operating parameter set with the environmental temperature being a preset temperature as a sample comparison unit includes:

dividing each sample cell into a plurality of temperature groups according to all ambient temperatures in the sample cell;

and selecting a temperature group of the sample unit, wherein the ambient temperatures of the sample unit are all preset temperatures, as a sample comparison unit.

Optionally, the comparing the operating parameter of the sample comparing unit with a standard value further comprises;

and carrying out averaging processing on a plurality of sample units in the sample comparison unit to obtain a mean value sample comparison unit.

Optionally, the averaging processing is performed on the sample comparison unit to obtain an average sample comparison unit;

dividing the sample comparison unit into a plurality of sample groups, wherein each sample group comprises relatively continuous sample units with the same number;

calculating the average value of the charging operation parameter and the average value of the discharging operation parameter of the charging operation parameter subunit and the discharging operation parameter subunit in each sample group at different time nodes;

and selecting the maximum value of the average value of the charging operation parameters and the minimum value of the average value of the discharging operation parameters as a mean value sample comparison unit of the sample group.

Optionally, the operation parameters include a charge operation parameter and a discharge operation parameter, the charge operation parameter includes a charge voltage and a charge current, and the discharge operation parameter includes a discharge voltage and a discharge current.

Optionally, the comparing the operating parameter of the sample comparing unit with a standard value includes: and comparing the charging current, the charging voltage and the discharging voltage in the operation parameters with standard values respectively.

Optionally, the obtaining the operating state of the photovoltaic power supply system according to the comparison result between the operating parameter of the sample comparison unit and the standard value includes:

and if the charging current is greater than a charging current standard value, the charging voltage is greater than a charging voltage standard value, and the discharging voltage is greater than a discharging voltage standard value, the photovoltaic power supply system operates normally.

Optionally, constructing the operating parameters corresponding to the time nodes into an operating parameter set by using the time nodes as tags includes:

and establishing an operation parameter key pair value, wherein the operation parameter key pair value takes a time node as an object, and the operation parameter corresponding to the time node is taken as an attribute of the object.

A second aspect of the embodiments of the present invention provides a device for detecting an operating state of a photovoltaic power supply system, including:

the operation parameter acquisition module is used for acquiring operation parameters corresponding to the photovoltaic power supply system and the time node, and the operation parameters at least comprise ambient temperature, voltage and current;

the processing module is used for constructing the operation parameters corresponding to the time nodes into an operation parameter set by taking the time nodes as labels; the operation parameter set is used for selecting the environment temperature as a preset temperature and is used as a sample comparison unit; the system is used for comparing the operating parameters of the sample comparison unit with standard values;

and the result output module is used for obtaining the operation state output of the photovoltaic power supply system according to the comparison result of the operation parameters and the standard values of the sample comparison unit.

A third aspect of the embodiments of the present invention provides a terminal, including a memory and a processor, where the memory is coupled to the processor; the memory stores instructions that, when executed by the processor, cause the processor to perform the method of embodiments of the present application.

A fourth aspect of the embodiments of the present invention provides a computer-readable medium having a program code executable by a processor, where the program code causes the processor to execute the method according to the embodiments of the present application.

According to the embodiment of the invention, the data of the photovoltaic power supply system is acquired, and the operation parameters corresponding to the time nodes are detected, compared and analyzed, so that the operation state and the fault reason of the photovoltaic power supply system can be quickly judged and obtained, the state detection efficiency and the fault reason detection efficiency of the photovoltaic power supply system are greatly improved, the passive one-by-one troubleshooting and cause determination mode is changed into the active positioning problem cause, the maintenance and overhaul efficiency is improved, and the maintenance cost is reduced. Meanwhile, the maintenance efficiency is improved, so that the maintenance time of the photovoltaic power supply system is shortened, and the production efficiency of the photovoltaic power supply system is improved.

Drawings

Fig. 1 is a flowchart of a method for detecting an operating state of a photovoltaic power supply system according to a first embodiment of the present invention;

fig. 2 is a flowchart of a method for detecting an operating state of a photovoltaic power supply system according to a second embodiment of the present invention;

fig. 3 is a flowchart of a method for detecting an operating state of a photovoltaic power supply system according to a third embodiment of the present invention;

FIG. 4 is a graph of the set of operating parameters for seven sample cells of sample set A:

FIG. 5a is a charge current plot of the charge run parameter sub-cell in the sample cell of sample set A;

FIG. 5b is a graph of the charge voltage of the charge run parameter sub-cell in the sample cell of sample set A;

FIG. 6a is a graph of the average value of the charge current versus the time node for a sample set A of charge operating parameters;

FIG. 6b is a graph of the average value of the charge voltage versus the time node for the charge operating parameter of sample set A;

FIG. 6c is a graph of the average value of the discharge voltage versus the time node for the discharge operating parameter of sample set A;

fig. 7 is a diagram of an operating state of the photovoltaic power supply system obtained according to a comparison result between the operating parameter of the sample comparison unit and the standard value.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The first invention provides a method for detecting the running state of a photovoltaic power supply system.

As shown in fig. 1, a first embodiment of the present invention provides a method for detecting an operation state of a photovoltaic power supply system, which includes steps S101 to S105.

S101, obtaining operation parameters corresponding to the photovoltaic power supply system and a time node, wherein the operation parameters at least comprise environment temperature, voltage and current.

When the operating state of the photovoltaic power supply system is monitored, the time node for acquiring the operating parameters can be every second, every minute or every hour, and if the collection precision of the operating parameters is improved, the operating parameters of the photovoltaic power supply system can be acquired in real time.

And S102, constructing the operation parameters corresponding to the time nodes into an operation parameter set by taking the time nodes as labels.

Specifically, in this embodiment, the time node is used as the tag, and the operating parameter of the photovoltaic power supply system at the certain time node can be quickly and accurately retrieved, so that the operating state of the photovoltaic power supply system at the certain time node can be more accurately determined.

S103, selecting an operation parameter set with the environment temperature as a preset temperature as a sample comparison unit.

According to different investigation and detection environments, the preset temperature can be automatically limited, so that the running state of the photovoltaic power supply system at the required ambient temperature is ensured to be obtained.

And S104, comparing the operating parameters of the sample comparison unit with the standard values.

And S105, obtaining the running state of the photovoltaic power supply system according to the comparison result of the running parameters and the standard values of the sample comparison unit.

Although the operating state of the photovoltaic power supply system can be quickly detected and determined as an implementation manner, the data result processing is inaccurate due to the large fluctuation range of the temperature interval of the preset temperature.

Therefore, in order to solve the above-mentioned defects, a second embodiment of the present application provides a photovoltaic power supply system detection method based on the above-mentioned embodiments, as shown in fig. 2, including S201 to S205.

S201, obtaining operation parameters corresponding to the photovoltaic power supply system and the time node, wherein the operation parameters at least comprise environment temperature, voltage and current.

The method comprises the steps of detecting and collecting the operating parameters of the photovoltaic power supply system by adopting a sensor and a data acquisition system, preferably detecting and collecting the operating parameters by adopting a data acquisition operation and maintenance monitoring system independently built by China iron tower companies, and then obtaining the operating parameters of the photovoltaic power supply system.

Specifically, the operating parameters include a charge operating parameter including an ambient temperature, a charge current, and a charge voltage, and a discharge operating parameter including an ambient temperature, a discharge current, and a discharge voltage.

S202, constructing the operation parameters corresponding to the time nodes into an operation parameter set by taking the time nodes as labels.

Specifically, in this embodiment, in order to improve the efficiency of data classification and the accuracy of data classification, the operation parameter set is embodied in the form of an operation parameter key pair value, the operation parameter key pair value takes a time node as an object, and an operation parameter corresponding to the time node is taken as an attribute of the object.

The operation parameter set is embodied in a key pair value form as follows: time { ambient temperature, voltage, current }, then the key pair value form of the set of charging operating parameters is: time { ambient temperature, charging voltage, charging current }, the key pair value form of the set of discharge operating parameters is: time { ambient temperature, discharge voltage, discharge current }.

S203, selecting an operation parameter set with the environment temperature as a preset temperature as a sample comparison unit.

Specifically, the method comprises the steps of dividing the operation parameter set into a plurality of temperature groups according to the ambient temperature in the operation parameter set;

the present embodiment includes dividing the parameter set into a plurality of temperature groups according to the ambient temperature in the operating parameter set; preferably divided into three temperature groups, including a low temperature group, a normal temperature group and a high temperature group, wherein the low temperature group comprises an operating parameter set with an ambient temperature of-10 ℃ to 10 ℃, the normal temperature group comprises an operating parameter set with an ambient temperature of 10 ℃ to 45 ℃, and the high temperature group comprises an operating parameter set with an ambient temperature of 45 ℃ to 60 ℃.

In addition, in S203, all the ambient temperatures in each temperature group are replaced by the same temperature label, and the temperature labels of different temperature groups are different.

And selecting a temperature group with the environment temperature as a preset temperature as a sample comparison unit.

And S204, comparing the operating parameters of the sample comparison unit with the standard values.

And S205, obtaining the running state of the photovoltaic power supply system according to the comparison result of the running parameters and the standard values of the sample comparison unit.

Although the above embodiment can ensure that the preset temperature can be detected quickly, and the influence of the ambient temperature on the accuracy of the final data structure is reduced, since there are many data points, if the data points are used directly, a large noise or deviation occurs, and the analysis result is influenced, the third embodiment of the present application provides a method for detecting a photovoltaic power supply system based on the above embodiments to overcome the above disadvantages, as shown in fig. 3 to 7, including S301 to S306.

S301, obtaining operation parameters of the photovoltaic power supply system corresponding to a time node t, wherein the operation parameters at least comprise environment temperature, voltage and current.

The method comprises the steps of detecting and collecting the operating parameters of the photovoltaic power supply system by adopting a sensor and a data acquisition system, preferably detecting and collecting the operating parameters by adopting a data acquisition operation and maintenance monitoring system independently built by China iron tower companies, and then obtaining the operating parameters of the photovoltaic power supply system.

Specifically, the operation parameters include a charge operation parameter and a discharge operation parameter, and the charge operation parameter includes a charge current I_INAnd a charging voltage V_INThe discharge operating parameter includes discharge current I_OUTAnd a discharge voltage V_OUT。

S302, the time node is taken as a label, and the operation parameters corresponding to the time node are constructed into an operation parameter set.

Specifically, the operation parameter set comprises a charging operation parameter set and a discharging operation parameter set, wherein the charging operation parameter set comprises an environment temperature T and a charging current I_INAnd a charging voltage V_INThe discharge operation parameter set comprises an ambient temperature T and a discharge current I_OUTAnd a discharge voltage V_OUT。

Optionally, in order to improve the data screening efficiency and accuracy, the operation parameter set is represented in the form of an operation parameter key pair value, the operation parameter key pair value takes the time node as an object, and the operation parameter corresponding to the time node is taken as an attribute of the object.

The key pair values of the set of operating parameters are of the general form: time { ambient temperature, voltage, current }, then the key pair value form of the set of charging operating parameters is: time { ambient temperature, charging voltage, charging current }, the key pair value form of the set of discharge operating parameters is: time { ambient temperature, discharge voltage, discharge current }.

In the actual implementation process, the acquired data are arranged as follows,

the plurality of sets of charge operating parameters includes INt₁{T₁，V_IN1，I_IN1}、INt₂{T₂，V_IN2，I_IN2}、INt₃{T₃，V_IN2，I_IN3}……INt_n{T_n，V_INn，I_INn}。

The sets of discharge operating parameters include OUTT₁{T₁，V_OUT1，I_OUT1}、OUTt₂{T₂，V_OUT2，I_OUT2}、OUTt₃{T₃，V_OUT2，I_OUT3}……OUTt_n{T_n，V_OUTn，I_OUTn}。

In this embodiment, the operating parameter set of 24 hours per day is divided into one sample unit, the operating parameters are recorded once per hour, and the operating parameter sets of different time points in one day are continuously recorded, for example, the operating parameter sets of each time node at 0, 1, 2, 3, 4-hour-.. 22, and 23 of 30 days in 4 months are used as one sample unit according to the time sequence. Instead of dividing by date, the consecutive 24 hours may be one sample unit, for example, from 9 hours on day 30 of month 4 to 9 hours on day 1 of month 5. Thus, each sample cell is chronologically composed of the operating parameter key pair values for the respective time node for 24 consecutive hours.

In addition, since the operation parameters include a charge operation parameter and a discharge operation parameter, each sample cell includes a charge operation parameter sub-cell and a discharge operation parameter sub-cell. Specifically, in the present embodiment, the charging operation parameter subunit is set from 9 hours to 15 hours of each day, and the discharging operation parameter subunit is set from 16 hours to 4 hours of each day.

S303, selecting an operation parameter set with the environment temperature as a preset temperature as a sample comparison unit.

The present embodiment includes dividing the parameter set into a plurality of temperature groups according to the ambient temperature in the operating parameter set; preferably divided into three temperature groups, including a low temperature group, a normal temperature group and a high temperature group, wherein the low temperature group comprises an operating parameter set with an ambient temperature of-10 ℃ to 10 ℃, the normal temperature group comprises an operating parameter set with an ambient temperature of 10 ℃ to 45 ℃, and the high temperature group comprises an operating parameter set with an ambient temperature of 45 ℃ to 60 ℃.

And screening the operation parameter key pair values meeting the conditions in the operation parameters, namely selecting the operation parameter set with the temperature T falling into the temperature interval of the normal temperature group, namely selecting the operation parameter set with the temperature T being less than or equal to 10 ℃ and less than or equal to 45 ℃ in the embodiment. Specifically, in S303, all the ambient temperatures in each temperature group are replaced with the same temperature tag, the temperature tags in different temperature groups are different, and the data are better classified and sorted by the temperature tags, so that the analysis efficiency is improved.

The temperature labels in this example are-1/0/1 corresponding to the low temperature group, the normal temperature group, and the high temperature group, respectively. And marking the environmental temperature T normalization of all the operation parameter sets of the low-temperature group as-1, marking the environmental temperature T normalization of all the operation parameter sets of the normal-temperature group as 0, and marking the environmental temperature T normalization of all the operation parameter sets of the high-temperature group as 1. The temperature label-1/0/1 in this embodiment is only an example, and is not limited, and the temperature label may also be replaced by other forms such as other words, letters, numbers, and the like, which are not described in detail in this embodiment.

Specifically, in this embodiment, the 24-hour operation parameter set is used as one sample unit, so that the ambient temperature of each operation parameter set of each sample unit needs to be compared with the preset temperature, if the ambient temperatures of 24 hours in the same day all meet the preset temperature, the sample unit in the day is determined to meet the preset temperature, and all the ambient temperatures of the sample unit are normalized and marked as 0, and can be used as a sample comparison unit. If any one of the 24-hour environmental temperatures in the same day does not meet the preset temperature, the sample unit in the same day does not meet the requirement and cannot be used as a sample comparison unit.

For example: the environmental temperature of 24 hours in the whole day of 20 days in 5 months meets 10 ℃ and T is less than or equal to 45 ℃, and then the sample unit on the day of 20 days in 5 months can be used as a sample comparison unit. The environmental temperature at 5, 21 and 14 days is 46 ℃, and the environmental temperatures at other time periods are consistent with 10 ℃ and less than T and less than or equal to 45 ℃, so that the sample unit at the day of 5, 21 and 21 days cannot be used as a sample comparison unit.

Marking all the environmental temperatures T of the sample units of the 5-month 20-day samples as required, and marking all the environmental temperatures T of the sample units of the 5-month 20-day samples as T0 in a normalized mode, so that the operating parameter key pair values of the 5-month 20-day samples are all in a T {0, V, I } form.

S304, carrying out averaging processing on a plurality of sample units in the sample comparison unit to obtain a mean value sample comparison unit.

First, the sample matching unit is divided into a plurality of sample groups, each sample group includes a same number of relatively continuous sample units, and in this embodiment, a sample unit that is relatively continuous for 7 days is preferably selected as one sample group. The term "sample unit" as used herein is relatively continuous, and is mainly understood to mean that only relatively continuous sample alignment units can be selected since sample units are not individually capable of being sample alignment units.

For example, in the period from 5 month 20 to 5 month 30, the environmental temperature of the sample units on 5 month 21 and 5 month 24 at a certain time does not meet the preset temperature, and the environmental temperatures of the sample units on other dates all meet the preset temperature, at this time, the sample units on 5 month 21 and 5 month 24 cannot be used as the sample comparison unit, and the sample units on other dates can be used as the sample comparison unit, so that the sample units on 20, 22, 23, 25, 26, 27 and 28 consecutive days are selected as a sample group. And on the 29 th day and the 30 th day, a sample group consisting of the sample units of seven days is formed by the sample units which accord with the preset temperature on the subsequent date, and so on, and a plurality of sample groups are obtained.

And then calculating the average value of the charging operation parameter and the average value of the discharging operation parameter of the charging operation parameter subunit and the discharging operation parameter subunit in each sample group at different time nodes.

In this embodiment, taking the charging operation parameter as an example, assuming that M sample groups are obtained in total, the method includes: sample set a, sample set B, sample set C … … sample set M,

as shown in fig. 4, the sample group a includes sample units of seven days, each of which includes a charge operation parameter subunit and a discharge operation parameter subunit, or seven groups of the charge operation parameter subunits and the discharge operation parameter subunits are extracted from the sample units of seven days, respectively.

The sample units of seven days are respectively marked as sample unit a₁Sample cell a₂..₇In the sample cell a₁Including a₁Charging operation parameter subunit of the same day, INt_1a1{0，V_INt1a1，I_INt1a1}，INt_2a2{0，V_INt2a1，I_INt2a1}，INt_3a3{0，V_INt3a1，I_INt3a1… … etc. a₁The combination of chronologically successive sets of charging operating parameters over a 24-hour period of the day, as shown in fig. 5a and 5b, are schematic diagrams of the charging current and charging voltage, respectively, of sample set a.

In the sample cell a₂Also includes a₂Charging operation parameter subunit of the same day, INt_1a2{0，V_INt1a2，I_INt1a2}，INt_2a2{0，V_INt2a2，I_INt2a2}，INt_3a2{0，V_INt3a2，I_INt3a2… … etc. a₂A combination of chronologically successive sets of charging operating parameters over a 24-hour period of the day.

The other sample units are analogized in turn until the sample group a₇Including INt_1a7{0，V_INt1a7，I_INt1a7}，INt_2a7{0，V_INt2a7，I_INt2a7}，INt_3a7{0，V_INt3a7，I_INt3a7… … etc. a₇A combination of chronologically successive sets of charging operating parameters over a 24-hour period of the day.

Wherein t is_1a1And t_1a2、t_1a3.....t_1a7Representing time nodes t corresponding to different sample units₁E.g. t_1a1Is a sample unit a₁At 14 in (1), then t_1a2Representative sample cell a₂At 14 in (1), the other t₁The same is true. Sample cell a₁Sample cell a₂..₇The other time nodes t are also uniformly and correspondingly recorded, and the charging operation parameter set of the corresponding time node t is recorded.

According to the sample unit a₁Sample cell a₂..₇The charging operation parameter subunit calculates the average value of the charging operation parameters of the sample group a at a certain time node t, and then connects the average values of the charging operation parameters of different time nodes to obtain the relation graphs 6a and 6b of the average values of the charging current and the charging voltage and the time node in the charging operation parameters of the seven sample units of the sample group a, wherein the specific calculation process is as follows;

selecting a sample unit a₁Sample cell a₂..₇Set of charging operation parameters at a certain time node t, e.g. sample cell a₁Sample cell a₂..₇Accumulating and summing the 12-hour charging operation parameters in each sample unit, and then dividing by 7 to obtain the average value INt of the 12-hour charging operation parameter set of seven sample units in the sample group A_ia{0，V_{INtia Mean value of}，I_{INtia Mean value of}Where INt_iaIs 12 hours.

According to the method, different time points INt are obtained by analogy in sequence_iaThe average values of the charging operation parameter sets of different time nodes are connected according to the time sequence to obtain a relation graph 5a and a relation graph 5b of the average values of the charging operation parameter sets of the sample units of the sample group A and the time nodes, and the horizontal axis is the time node.

The calculation process of the discharging operation parameter and the charging operation parameter are not repeated herein, and a relationship diagram between the average value of the discharging operation parameter set of the sample unit of the sample group a and the time node is finally obtained, and a relationship diagram between the average value of the discharging voltage and the time node is selected, as shown in fig. 6 c.

And finally, selecting the maximum value of the average value of the charging operation parameters and the minimum value of the average value of the discharging operation parameters as a mean value sample comparison unit of the sample group.

In this embodiment, according to the relationship between the average value of the charging operation parameter set of the sample unit of the sample group a and the time node, the maximum value V in the average value of the charging operation parameter set of the sample group a is obtained_INmaxtiaAnd I_INmaxtiaThe average value sample comparison unit as the charge operation parameter of the sample group a is an operation parameter for comparison with a standard value in S305.

The same calculation method as that of the charging operation parameter set is adopted for the discharging operation parameter set in the sample set A, the average value of the operation parameter sets of the sample units at each time node is obtained firstly, and then the maximum value V in the average value of the discharging operation parameter set is obtained from the relation between the average value of the discharging operation parameter set of the sample units and the time nodes_OUTmintiaAnd I_IOUTmintiaAs a mean value sample comparison unit of the discharge operation parameters of the sample group a.

The other sample groups adopt the same processing method, which is not described herein.

By utilizing the averaging treatment of the operation parameters and then comparing, the interference of external accidental factors on the operation parameters in the operation of the equipment is eliminated, the accuracy of data analysis is ensured, and the high efficiency and the accuracy of an analysis result are ensured.

S305, comparing the operation parameters of the sample comparison unit with the standard values.

Specifically, in this embodiment, the mean value sample comparison unit of the sample group a is preferably compared with the standard value. Charging voltage V that is the maximum of the averages of the charging operating parameter set of the sample group A_INmaxtiaAnd a charging current I_INmaxtiaAnd a discharge voltage V of the minimum value of the mean values of the set of discharge operating parameters_OUTmintiaRespectively compared with the labeled values, i.e. the charging current I_INmaxtiaAnd a standard value I_{IN Standard value}Charging voltage V_INmaxtiaAnd a standard value V_{IN standard value}Discharge voltage V_OUTmintiaAnd a standard value V_{OUT Standard value}The comparison was performed separately.

In this embodiment, I_INThe trend of the charging current can be used for judging whether the power generation efficiency, the charging parameters and the like of the photovoltaic system are abnormal or not; v_INThe voltage of the storage battery during charging is reflected by the trend of the voltage; v_OUTThe voltage of the storage battery during discharging reflects the shortage condition of the electric quantity of the storage battery.

And S306, as shown in the figure 7, obtaining the running state of the photovoltaic power supply system according to the comparison result of the running parameters of the sample comparison unit and the standard values, obtaining the running state of the photovoltaic power supply system of the sample group A by utilizing the running parameter set of the sample unit of the sample group A within seven days, and similarly obtaining the running state results of other sample groups by utilizing the running parameter sets of other sample groups.

I_INmaxtia≥I_{IN Standard value}

V_INmaxtia≥V_{IN Standard value}

V_OUTmintia≥V_{OUT Standard value}

In this embodiment, if the charging current I_INmaxtiaGreater than or equal to the standard value of charging current I_{IN Standard value}And a charging voltage V_INmaxtiaGreater than or equal to charging voltage standard V_{IN Standard value}And a discharge voltage V_OUTmintiaGreater than or equal to the discharge voltage standard value V_{OUT Standard value}The photovoltaic power supply system works normally, wherein V_{IN Standard value}And V_{OUT Standard value}May be the same value.

If comprising the charging current I_INmaxtiaGreater than or equal to the standard value of charging current I_{IN Standard value}And a charging voltage V_INmaxtiaGreater than or equal to charging voltage standard V_{IN Standard value}And a discharge voltage V_OUTmintiaLess than the discharge voltage reference value V_{OUT Standard value}And the effective capacity of the storage battery of the photovoltaic power supply system is smaller than the electricity consumption of the load for the discharge time.

If the charging current I_INmaxtiaGreater than or equal to the standard value of charging current I_{IN Standard value}And a charging voltage V_INmaxtiaLess than charging voltage level V_{IN Standard value}And a discharge voltage V_OUTmintiaLess than the discharge voltage reference value V_{OUT Standard value}And if the effective capacity of the photovoltaic power supply system is less than the effective capacity of the storage battery, or the effective capacity of the storage battery is less than the electricity consumption of the load, and the discharge time is long.

If the charging current I_INmaxtiaLess than the standard value of charging current I_{IN Standard value}And a charging voltage V_INmaxtiaLess than charging voltage level V_{IN Standard value}And a discharge voltage V_OUTmintiaLess than the discharge voltage reference value V_{OUT Standard value}And if so, setting the parameters of the charging current of the storage batteries of the photovoltaic power supply system wrongly, or setting the effective capacity of the photovoltaic power supply system and the generating time to be less than the effective capacity of the storage batteries, or setting the effective capacity of the storage batteries to be less than the power consumption of the load and the discharging time.

If the charging current I_INmaxtiaGreater than or equal to the standard value of charging current I_{IN Standard value}And a charging voltage V_INmaxtiaLess than charging voltage level V_{IN Standard value}And a discharge voltage V_OUTmintiaaGreater than or equal to the discharge voltage standard value V_{OUT Standard value}And the effective capacity of the photovoltaic power supply system is less than the effective capacity of the storage battery.

If the charging current I_INmaxtiaLess than the standard value of charging current I_{IN Standard value}And a charging voltage V_INmaxtiaLess than charging voltage level V_{IN Standard value}And a discharge voltage V_OUTmintiaGreater than or equal to the discharge voltage standard value V_{OUT Standard value}And if the current parameter of the storage battery is wrong, or the effective capacity of the photovoltaic power supply system is less than the effective capacity of the storage battery.

If the charging current I_INmaxtiaLess than the standard value of charging current I_{IN Standard value}And is charged with electricityVoltage V_INmaxtiaGreater than or equal to charging voltage standard V_{IN Standard value}And a discharge voltage V_OUTmintiaGreater than or equal to the discharge voltage standard value V_{OUT Standard value}And the setting of the uniform current parameter of the storage battery is wrong.

If the charging current I_INmaxtiaLess than the standard value of charging current I_{IN Standard value}And a charging voltage V_INmaxtiaGreater than or equal to charging voltage standard V_{IN Standard value}And a discharge voltage V_OUTmintiaLess than the discharge voltage reference value V_{OUT Standard value}And if the storage battery uniform current parameter is set wrongly, or the effective capacity of the storage battery is smaller than the load power consumption and the discharge duration.

A second aspect of the embodiments of the present invention provides a device for detecting an operating state of a photovoltaic power supply system, including:

the operation parameter acquisition module is used for acquiring operation parameters corresponding to the photovoltaic power supply system and the time node, and the operation parameters at least comprise ambient temperature, voltage and current;

the processing module is used for constructing an operation parameter set by using the time node as a label and the operation parameters corresponding to the time node; the system comprises a sample comparison unit, a comparison unit and a comparison unit, wherein the sample comparison unit is used for executing and selecting an operation parameter set with the environment temperature as a preset temperature; the device is used for comparing the operating parameters of the sample comparison unit with the standard values;

and the result output module is used for obtaining the operation state output of the photovoltaic power supply system according to the comparison result of the operation parameters and the standard values of the sample comparison unit.

A third aspect of embodiments of the present invention provides a terminal, including a memory and a processor, where the memory is coupled to the processor; the memory stores instructions that, when executed by the processor, cause the processor to perform the methods of embodiments of the present application.

A fourth aspect of the embodiments of the present invention provides a computer-readable medium having a program code executable by a processor, where the program code causes the processor to execute the method of the embodiments of the present application.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (14)

1. A method for detecting the running state of a photovoltaic power supply system is characterized by comprising the following steps:

acquiring operating parameters corresponding to a photovoltaic power supply system and a time node, wherein the operating parameters at least comprise ambient temperature, voltage and current;

constructing the operation parameters corresponding to the time nodes into an operation parameter set by taking the time nodes as labels;

selecting the operation parameter set with the environment temperature as a preset temperature as a sample comparison unit;

comparing the operating parameters of the sample comparison unit with standard values;

and obtaining the operating state of the photovoltaic power supply system according to the comparison result of the operating parameters of the sample comparison unit and the standard value.

2. The method according to claim 1, wherein the selecting the operating parameter set with the ambient temperature being a preset temperature as a sample comparison unit comprises:

dividing the parameter set into a plurality of temperature groups according to the ambient temperature in the parameter set;

and selecting the temperature group with the environment temperature as a preset temperature as a sample comparison unit.

3. The method according to claim 2, wherein the dividing the set of operating parameters into a plurality of temperature groups according to the ambient temperature in the set of operating parameters comprises:

and replacing all the ambient temperatures in each temperature group by the same temperature label, wherein the temperature labels of different temperature groups are different.

4. The method for detecting the operating state of the photovoltaic power supply system according to claim 2, wherein before the step of selecting the operating parameter set with the environmental temperature as the preset temperature as the sample comparison unit, the method further comprises:

and taking a time-continuous operation parameter set as sample units, wherein each sample unit comprises a charging operation parameter subunit and a discharging operation parameter subunit.

5. The method for detecting the operating state of the photovoltaic power supply system according to claim 4, wherein the selecting the operating parameter set with the environmental temperature being a preset temperature as a sample comparison unit comprises:

dividing each sample cell into a plurality of temperature groups according to all ambient temperatures in the sample cell;

and selecting a temperature group of the sample unit, wherein the ambient temperatures of the sample unit are all preset temperatures, as a sample comparison unit.

6. The method for detecting the operating state of the photovoltaic power supply system according to claim 5, wherein the step of comparing the operating parameter of the sample comparison unit with a standard value further comprises the step of comparing the operating parameter of the sample comparison unit with a standard value;

and carrying out averaging processing on a plurality of sample units in the sample comparison unit to obtain a mean value sample comparison unit.

7. The method for detecting the operating state of the photovoltaic power supply system according to claim 6, wherein the step of performing averaging processing on the sample comparison unit to obtain an average sample comparison unit comprises;

dividing the sample comparison unit into a plurality of sample groups, wherein each sample group comprises relatively continuous sample units with the same number;

calculating the average value of the charging operation parameter and the average value of the discharging operation parameter of the charging operation parameter subunit and the discharging operation parameter subunit in each sample group at different time nodes;

and selecting the maximum value of the average value of the charging operation parameters and the minimum value of the average value of the discharging operation parameters as a mean value sample comparison unit of the sample group.

8. The method for detecting the operating state of the photovoltaic power supply system according to claim 1,

the operation parameters comprise charging operation parameters and discharging operation parameters, the charging operation parameters comprise charging voltage and charging current, and the discharging operation parameters comprise discharging voltage and discharging current.

9. The method for detecting the operating state of the photovoltaic power supply system according to claim 8, wherein the comparing the operating parameters of the sample comparing unit with standard values respectively comprises:

and comparing the charging current, the charging voltage and the discharging voltage in the operation parameters with standard values respectively.

10. The method for detecting the operating state of the photovoltaic power supply system according to claim 9, wherein the obtaining the operating state of the photovoltaic power supply system according to the comparison result between the operating parameter of the sample comparison unit and the standard value comprises:

and if the charging current is greater than a charging current standard value, the charging voltage is greater than a charging voltage standard value, and the discharging voltage is greater than a discharging voltage standard value, the photovoltaic power supply system operates normally.

11. The method for detecting the operating state of the photovoltaic power supply system according to claim 1, wherein constructing the operating parameters corresponding to the time nodes into an operating parameter set by using the time nodes as tags comprises:

and establishing an operation parameter key pair value, wherein the operation parameter key pair value takes a time node as an object, and the operation parameter corresponding to the time node is taken as an attribute of the object.

12. The utility model provides a photovoltaic power supply system running state detection device which characterized in that includes:

the operation parameter acquisition module is used for acquiring operation parameters corresponding to the photovoltaic power supply system and the time node, and the operation parameters at least comprise ambient temperature, voltage and current;

the processing module is used for constructing the operation parameters corresponding to the time nodes into an operation parameter set by taking the time nodes as labels; the operation parameter set is used for selecting the environment temperature as a preset temperature and is used as a sample comparison unit; the system is used for comparing the operating parameters of the sample comparison unit with standard values;

and the result output module is used for obtaining the operation state output of the photovoltaic power supply system according to the comparison result of the operation parameters and the standard values of the sample comparison unit.

13. A terminal comprising a memory and a processor, the memory coupled with the processor; the memory stores instructions that, when executed by the processor, cause the processor to perform the method of any of claims 1 to 11.

14. A computer-readable medium having program code executable by a processor, the program code causing the processor to perform the method of any one of claims 1 to 11.

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