KR102291365B1 - Apparatus and method for collecting history data of solar power system - Google Patents

Abstract

The present invention provides an apparatus for collecting history data of a photovoltaic device including a plurality of facilities for generating electricity from sunlight, comprising: a real-time measurement unit; history data storage unit; and a monitoring unit, comprising: a real-time measurement step of collecting measurement data in real time from at least one of the plurality of facilities; a history data storage step of storing the measurement data for each preset storage period, managing the history of the measurement data, and separately storing the measurement values and the state values of the corresponding equipment; and generating an alarm when the value of the first count field exceeds a preset abnormality detection determination criterion. Therefore, the present invention can save the storage capacity of records by preventing the storage of duplicate data generated due to the operational characteristics of the photovoltaic device, and thereby, by improving the inquiry performance, the history data of the photovoltaic device It has the advantage of being able to manage it effectively. In addition, there is an advantage in that it is possible to shorten the time for troubleshooting in the power plant.

Description

Photovoltaic power generation device history data collection device and method

The present invention relates to a photovoltaic device history data collection device and method, and more particularly, to a photovoltaic device history data collection device and the same for efficiently storing/managing history data of a photovoltaic device it's about how

Recently, due to concerns about energy depletion and environmental pollution, solar power generation using solar energy to produce electricity on a large scale has been in the spotlight. Such photovoltaic power generation has the advantage that there is no fuel cost and there is no air pollution or waste generation because it uses unlimited, pollution-free solar energy.

On the other hand, the amount of power generation of such a photovoltaic device is greatly affected by environmental factors such as weather and time. Therefore, it is necessary to continuously detect these environmental factors. In addition, since the photovoltaic device requires a relatively large area to absorb a large amount of sunlight, it is often located in a remote location away from a general residential area or the work area of a manager who manages the photovoltaic device.

For this reason, the photovoltaic device includes a separate data collection device that collects and transmits the state of the photovoltaic device to the outside.

The data collection device collects data in real time from various facilities (eg, solar string connection panel, inverter, transformer, etc.) included in the photovoltaic device, and stores the data at preset intervals, Manage historical data.

For example, the data collection device may collect data including current, voltage, temperature, fire state, current abnormal state, and voltage abnormal state from the solar panel in real time. Alternatively, the data collection device includes DC voltage/current, three-phase voltage/current, power factor, frequency, inverter temperature, inverter operation status (MPPT, stand by, sleep, etc.) Data can be collected in real time. And, by storing the data collected in real time every preset period, it is possible to manage the history data of the solar panel or inverter.

However, the collected data includes analog measurement values for each facility and state values of the facilities. For example, real-time data collected from the solar panel may include analog measurement values including current, voltage, temperature, and the like, and state values including fire state, current abnormal state, voltage abnormal state, and the like.

At this time, the analog measurement values change frequently, but the state values of the facilities change relatively few times. However, since the conventional data collection apparatus stores data for each type of equipment, the analog measurement value and the state value of the equipment are stored in the same period. Therefore, in the case of the state values of the facilities, there is a characteristic that there is a lot of redundantly stored data.

In addition, in the case of analog numerical values such as voltage and current due to the characteristics of the photovoltaic device, a value of '0' is maintained while not generating power or there is no change in the value. Since the collected data is stored, duplicate records are stored for each facility.

That is, in the conventional data collection apparatus, duplicate data is stored or records are duplicated frequently, which results in wasted data storage space and poor query performance.

Korean Patent No. 10-1950456 (“Data Collection Device of Solar Power Generation Device”)

Accordingly, an object of the present invention is to provide an apparatus and method for collecting history data of a photovoltaic device capable of saving the storage capacity of a record by preventing the storage of redundant data generated due to operational characteristics of the photovoltaic device.

Another object of the present invention is to provide an apparatus and method for collecting history data of a photovoltaic device that can efficiently manage the history data of the photovoltaic device by improving inquiry performance.

In order to achieve the above object, the history data collection device of the photovoltaic device provided in the present invention is the history data collection device of the photovoltaic device including a plurality of facilities for generating electricity from sunlight, the plurality of a real-time measurement unit that collects measurement data in real time from at least one of the facilities; a history data storage unit that stores the measurement data for each preset storage period, manages the history of the measurement data, and stores the measurement values and state values of the corresponding equipment separately; and a monitoring unit that provides a user interface and displays at least one of the real-time measurement data collected by the real-time measurement unit and the history data stored in the history data storage unit based on an input signal.

Preferably, the real-time measurement unit includes: time information from at least one of the plurality of facilities; facility identification information; at least one measurement value preset as data measurable in a corresponding facility; And it is possible to collect measurement data including at least one state value preset as data indicating the state of the corresponding equipment.

Preferably, the history data storage unit includes: a measurement value storage unit for extracting and storing time information, equipment identification information and measurement values from the measurement data; and a state value storage unit for extracting and storing time information, equipment identification information, and state values from the measurement data, wherein the measurement value storage unit further includes a first count field for counting and storing the number of occurrences of the measurement value duplicate data and the state value storage unit may further include a second count field for counting and storing the number of occurrences of duplicate state value data.

Preferably, the measurement value storage unit does not store the duplicate data when the measurement values included in the measurement data overlap with the measurement values included in the previous measurement data transmitted from the corresponding facility, and the first count field You can only increase the value.

Preferably, the monitoring unit monitors the first count field value, recognizes the number of duplicates of the corresponding data based on the first count field value, and when the number of duplicates exceeds a preset abnormality detection determination criterion, can generate an alarm.

Preferably, the state value storage unit does not store the duplicate data when the state values included in the measurement data overlap with the state values included in the previous measurement data transmitted from the corresponding equipment, and the second count field You can only increase the value.

In addition, in order to achieve the above object, the history data collection method of the photovoltaic device provided in the present invention is a method for collecting the history data of the photovoltaic device including a plurality of facilities for generating electricity from sunlight, the a real-time measurement step of collecting measurement data in real time from at least one of a plurality of facilities; and a history data storage step of storing the measurement data for each preset storage period, managing the history of the measurement data, and separately storing the measurement value and the state value of the corresponding facility.

Preferably, the real-time measurement step includes: time information from at least one of the plurality of facilities; facility identification information; at least one measurement value preset as data measurable in a corresponding facility; And it is possible to collect measurement data including at least one state value preset as data indicating the state of the corresponding equipment.

Preferably, the history data storage step extracts and stores time information, equipment identification information and measurement values from the measurement data, and the measurement values included in the measurement data are included in the previous measurement data transmitted from the corresponding equipment. a measurement value storage step of increasing only the first count field value for counting the number of occurrences of the measurement value overlapping data, without storing the redundant data, if it overlaps with the measured value; and extracting and storing time information, equipment identification information, and state values from the measurement data, but when the state values included in the measurement data overlap with the state values included in the previous measurement data transmitted from the corresponding equipment, the The method may include a state value storing step of increasing only a second count field value for counting the number of occurrences of the state value duplicate data without storing the duplicate data.

Preferably, the method for collecting history data of the photovoltaic device may further include an alarm generating step of generating an alarm when the first count field value exceeds a preset abnormality detection determination criterion.

The apparatus and method for collecting history data of a photovoltaic device of the present invention can save the storage capacity of the record by preventing the storage of duplicate data generated due to the operational characteristics of the photovoltaic device, and thereby, the inquiry performance By improving the , there is an advantage that can efficiently manage the history data of the photovoltaic device. In addition, by utilizing the duplicate count that counts the number of occurrences of duplicate data, it is possible to quickly determine whether the equipment is operating abnormally. Due to this, there is an advantage in that it is possible to shorten the time for troubleshooting in the power plant.

1 is a schematic block diagram of an apparatus for collecting history data of a photovoltaic device according to an embodiment of the present invention.
2 is a schematic processing flow diagram of a method for collecting history data of a photovoltaic device according to an embodiment of the present invention.
3 is a diagram illustrating an example of a data format for real-time measurement data collected by a history data collecting device of a photovoltaic device according to an embodiment of the present invention.
4 to 6 are views for explaining the effects of the present invention as described above.
7 is a diagram illustrating an example of storing history data when an abnormality of a specific facility is detected according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings, but it will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily practice the present invention. However, the present invention may be embodied in various different forms and is not limited to the embodiments described herein. On the other hand, in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification. In addition, even if the detailed description is omitted, descriptions of parts that can be easily understood by those skilled in the art are omitted.

Throughout the specification and claims, when a part includes a certain element, it means that other elements may be further included, rather than excluding other elements, unless otherwise stated.

1 is a schematic block diagram of an apparatus for collecting history data of a photovoltaic device according to an embodiment of the present invention. Referring to FIG. 1 , a history data collection apparatus 100 of a solar power generation device including a plurality of facilities generating electricity from sunlight includes a real-time measurement unit 110 , a history data storage unit 120 , and a monitoring unit. 130 and a control unit 140 .

The real-time measurement unit 110 collects measurement data in real time from at least one of the plurality of facilities (ie, field facilities). To this end, the real-time measurement unit 110 may further include a communication interface for performing communication with each of the plurality of facilities. In addition, the measurement data collected by the real-time measurement unit 110 from the plurality of facilities includes 'time information/facility identification information/measured value/state value'. In this case, the measured value is at least one measured value preset as data measurable in the corresponding equipment, and the state value is at least one preset state value as data indicating the state of the corresponding equipment. The reason for pre-setting the measured values and state values for each equipment as described above is that the types of data measured and the types of states requiring monitoring are different for each equipment. For example, if the facility type identified by the facility identification information is 'connection board', the corresponding measured value is 'voltage/current/temperature', and the corresponding state value is 'fire/current abnormal/voltage abnormal' can be

The history data storage unit 120 stores the measurement data every preset storage period in order to manage the history of the measurement data. At this time, the history data storage unit 120 separates and stores the measured value and the state value of the corresponding facility. This is to lower the storage rate of duplicate data by separating the state value with a relatively high duplicate data generation rate from the measurement value that does not. To this end, the history data storage unit 120 includes a measurement value management DB 122 and a state value management DB 124 , and the measurement value management DB 122 receives time information, equipment identification information and measurement from the measurement data. The values are extracted and stored, and the state value management DB 124 extracts and stores time information, equipment identification information and state values from the measurement data. At this time, the measurement value management DB 122 further includes a first count field for counting and storing the measurement value duplicate data, and the status value management DB 124 is a second count field for counting and storing the duplicate state value data. may further include. In addition, the history data storage unit 120 does not store the duplicate data when the measurement value or state value included in the measurement data collected from a specific facility overlaps the value of the previous measurement data collected from the corresponding facility, and the Increment only the first or second count field value. This is in order to be able to determine whether the operation of the equipment corresponding to the first and second count field values is abnormal.

The monitoring unit 130 displays various data collected through the history data collection device 100 of the photovoltaic device and the operating state of the history data collection device 100 of the photovoltaic device. In particular, the monitoring unit 130 may display at least one of the real-time measurement data collected by the real-time measurement unit 110 and the history data stored in the history data storage unit 120 . To this end, the monitoring unit 130 may provide a user interface and operate based on a user's input signal.

In addition, the monitoring unit 130 receives the first and second count field values through the history data storage unit 120 , and determines whether the operation of the facility is abnormal based on the first and second count field values. can That is, the monitoring unit 130 recognizes the number of duplicates of the corresponding data based on the value of the first count field, and when the number of duplicates exceeds a preset abnormality detection determination criterion, it is determined that an abnormality has occurred in the corresponding equipment and an alarm can cause For example, it is common for real-time measured values of field facilities to change frequently during a time period in which normal power generation is performed. ) determines that an error has occurred in the corresponding on-site facility and may generate an alarm.

The controller 140 generally controls the operation of the history data collection apparatus 100 of the solar power generation device based on a preset control algorithm or a user's manipulation signal. To this end, the control unit 140 may output a control signal to the real-time measurement unit 110 , the history data storage unit 120 , and the monitoring unit 130 .

2 is a schematic flowchart of a method for collecting history data of a photovoltaic device according to an embodiment of the present invention. 1 and 2 , a method for collecting history data of a photovoltaic device according to an embodiment of the present invention is as follows.

First, in step S110, the real-time measurement unit 110 collects measurement data in time from one of a plurality of facilities included in the solar power generation device to generate electricity from sunlight. In this case, the measurement data may include 'time information/equipment identification information/measured value/state value'. The 'measured value' is data that can be measured in the corresponding facility, and is at least one preset measured value, and the 'state value' is data indicating the state of the corresponding facility and is at least one preset state value. The reason for pre-setting the measured values and state values for each equipment as described above is that the types of data measured and the types of states requiring monitoring are different for each equipment. For example, if the facility type identified by the facility identification information is 'connection board', the corresponding measured value is 'voltage/current/temperature', and the corresponding state value is 'fire/current abnormal/voltage abnormal' can be

3 is a diagram illustrating an example of a data format for the measurement data, and shows an example of a data format for measurement data received from a connection panel installed in the field. Referring to FIG. 3 , the measurement data 10 is composed of a header area (A) and a data area (Data) (B), and the data area (Data) (B) is again a measurement value storage area (B1). ) and a state value storage area (B2). At this time, the header area (Header) (A) includes the time information (TIME STAMP) 11 and the facility ID 12, and when the facility corresponding to the information stored in the facility ID 12 is a connection group, the measured value Voltage 13, current 14, and temperature 15 are stored in storage area B1, and fire 16, current abnormality 17, and voltage abnormality 18 information are stored in state value storage region B2, respectively. can be

Meanwhile, in step S120 of FIG. 2 , the history data storage unit 120 stores the measurement data for each preset storage period, and manages the history of the measurement data. At this time, in step S120, the measured value and the state value of the corresponding equipment are stored separately. This is to reduce the storage ratio of redundant data by separately storing state values with a relatively high rate of duplicate data and measurement values that do not. To this end, step S120 includes a measurement value storage step of extracting and storing time information, equipment identification information and measurement values from the measurement data, and a state of extracting and storing time information, equipment identification information and state values from the measurement data It may include a value storage step, wherein each of the measurement value storage step and the state value storage step counts only the number of occurrences of the duplicate data without storing duplicate data. That is, in each of the measurement value storage step and the state value storage step, when the measurement value or state value extracted from the measurement data is the same as the previously stored measurement value or state value, a new measurement value or state value is not stored, Only the number of occurrences of the duplicate data is increased. On the other hand, each of the measurement value storage step and the state value storage step, In order to manage the number of occurrences of the duplicate data, a first or second count field may be generated and the number of occurrences of the duplicate data may be stored in the first or second count field.

In addition, in step S130, the monitoring unit 130 may determine whether the operation of the facility is abnormal based on the first and second count field values. That is, in step S130, the number of duplicates of the corresponding data is recognized based on the value of the first count field, and when the number of duplicates exceeds a preset abnormality detection determination criterion, it is determined that an abnormality has occurred in the corresponding equipment and an alarm is generated can do it For example, it is common for real-time measured values of field facilities to change frequently during the time period in which normal power generation is performed. It is determined that an abnormality has occurred in the corresponding on-site facility and an alarm can be generated.

4 to 6 are diagrams for explaining the effect of the present invention as described above, FIG. 4 is an example of historical data collected/stored by a conventional method, and FIG. An example of the history data is shown, and FIG. 4 (b) shows an example of the history data collected/stored during the power generation stop time period. Meanwhile, FIG. 5 is an example of historical data collected/stored during the power generation time period according to an embodiment of the present invention. indicates. In addition, FIG. 6 is an example of historical data collected/stored during the power generation stop time period according to an embodiment of the present invention. indicates

4 (a) and 5, when comparing the case of collecting/storing historical data according to the prior art and according to an embodiment of the present invention in the power generation time period, the historical data for the state values of the facilities are significantly can be seen to decrease. That is, in the conventional case, as illustrated in (a) of FIG. 4 , by collecting/storing the corresponding data at preset intervals regardless of whether the state value of the facility changes or not, the data is stored even when there is no change in the state value at all. On the other hand, in the present invention, when there is no change in the state value, the storage of duplicate data can be significantly reduced by increasing only the count in the state where only one data is stored, as illustrated in FIG. 5(b). have.

4(b) and 6, when comparing the case of collecting/storing historical data according to the prior art and according to an embodiment of the present invention in the power generation stop time period, the history is much superior to the case of the power generation time period It can be seen that the amount of data storage decreases. That is, in the conventional case, as illustrated in (b) of FIG. 4, corresponding data must be collected/stored every preset period even when there is no measurement value change due to power generation stop, whereas the present invention is shown in FIG. As exemplified in , the storage of redundant data can be further reduced by increasing the count only if there is no change in the data value in the case of the measured value as well as the state value.

7 is a diagram illustrating an example of storing history data when an abnormality of a specific facility is detected according to an embodiment of the present invention. Referring to FIG. 7 , between 9:00 am and 9:07 am, the generation time zone, the measured value continues to change in the case of the equipment with ID 'JB_A002', whereas the duplicate count is ' in the case of equipment with ID 'JB_A001' It can be seen that 7'. Therefore, with reference to the data, it is possible to determine that the equipment 'JB_A001' is operating abnormally. Due to this, there is an advantage in that it is possible to shorten the time for troubleshooting in the power plant.

In the exemplary system described above, the methods are described on the basis of a flowchart as a series of steps or blocks, however, the present invention is not limited to the order of steps, and some steps may occur in a different order or concurrent with other steps as described above. can

In addition, those skilled in the art will understand that the steps shown in the flowchart are not exhaustive and that other steps may be included or that one or more steps in the flowchart may be deleted without affecting the scope of the present invention.

Claims (10)

In the history data collection device of a solar power generation device including a plurality of facilities for generating electricity from sunlight,
Collect measurement data in real time from at least one of the plurality of facilities, and use time information, facility identification information, at least one measurement value preset as data measurable in the corresponding facility, and data measurable in the corresponding facility a real-time measurement unit that collects measurement data including at least one preset state value;
By storing the measurement data at each preset storage period, but managing the history of the measurement data, in order to lower the storage rate of redundant data, at least one measurement value and at least one state value included in each measurement data are separated and a history data storage unit for storing; and
A monitoring unit that provides a user interface and displays at least one of the real-time measurement data collected by the real-time measurement unit and the history data stored in the history data storage unit based on an input signal,
The history data storage unit
Time information, equipment identification information, and measurement values are extracted and stored from each of the measurement data, and a first count field for counting and storing the number of times the measurement values overlap, the measurement values included in the measurement data, a measurement value storage unit that increases only the first count field value without storing the duplicate data when overlapping with the measurement values included in the previous measurement data transmitted from the corresponding facility; and
Time information, equipment identification information, and state values are extracted and stored from each of the measurement data, and a second count field for counting and storing the number of times the state values overlap, the state values included in the measurement data, Solar power generation, characterized in that it includes a state value storage unit that increases only the second count field value without storing the duplicate data when it overlaps with the state values included in the previous measurement data transmitted from the corresponding facility. The device's historical data collection device. delete delete delete According to claim 1, wherein the monitoring unit
monitoring the first count field value;
Recognizing the number of duplicates of the corresponding data based on the value of the first count field, and generating an alarm when the number of duplicates exceeds a preset abnormality detection determination criterion . delete In the method for collecting history data of a solar power generation device including a plurality of facilities for generating electricity from sunlight,
Collect measurement data in real time from at least one of the plurality of facilities, and use time information, facility identification information, at least one measurement value preset as data measurable in the corresponding facility, and data measurable in the corresponding facility a real-time measurement step of collecting measurement data including at least one preset state value; and
By storing the measurement data at each preset storage period, but managing the history of the measurement data, in order to lower the storage rate of redundant data, at least one measurement value and at least one state value included in each measurement data are separated and a history data storage step of storing the
The history data storage step is
Time information, equipment identification information, and measurement values are extracted and stored from each of the measurement data, but when the measurement values included in the measurement data overlap with the measurement values included in the previous measurement data transmitted from the corresponding equipment, the a measurement value storage step of increasing only the first count field value for counting the number of occurrences of the measurement value overlapping data without storing the redundant data; and
Time information, equipment identification information, and state values are extracted and stored from each of the measurement data, but when the state values included in the measurement data overlap with the state values included in the previous measurement data transmitted from the corresponding equipment, the The method of collecting history data of a photovoltaic device, comprising: a state value storage step of increasing only a second count field value for counting the number of occurrences of the state value duplicate data without storing the duplicate data. delete delete The method of claim 7, wherein the method for collecting historical data of the photovoltaic device comprises:
The method of claim 1, further comprising: generating an alarm when the first count field value exceeds a preset abnormality detection criterion.

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