JP2011134862A - Photovoltaic power generation system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a photovoltaic power generation system that can determine abnormal conditions of a photovoltaic power generation device, even if a detector is not provided for every individual string array. <P>SOLUTION: The photovoltaic power generation system includes a plurality of photovoltaic power generation devices and a central monitoring unit 80 which supervises the power generation state of each photovoltaic power generation device, while being connected to the plurality of photovoltaic power generation devices through a communication means, and transmits and receives information about the generated power measured by a power measuring portion 41 and the power generation of each photovoltaic power generation device between the photovoltaic power generation device ID001 and the central monitoring unit 80. In the display screen of the central monitoring unit display portion, a power generation index showing a power generation capability of each photovoltaic power generation device is so displayed as to be in contrast with the position where each photovoltaic power generation device is installed. Moreover, the plurality of photovoltaic power generation devices are constituted so as to be grouped, and the photovoltaic power generation devices showing power generation indexes lower than a standard value in the group is determined to be abnormal. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a photovoltaic power generation system in which a power generation index indicating a power generation capability of each photovoltaic power generation apparatus is displayed on a display screen indicating the installation positions of a plurality of photovoltaic power generation apparatuses.

  As the amount of carbon dioxide generated increases, global warming is progressing. Natural energy is used as a measure to suppress carbon dioxide, and solar power generation using inexhaustible sunlight as an energy source is attracting attention as clean energy. A large-scale solar power generation system with a capacity of several megawatts is installed on a large site. On the other hand, 2-5 kilowatts of small-scale power generators are installed on the rooftops of ordinary houses. In order to disseminate many such small-scale power generators, there is a need to develop a stable system that can reduce the number of parts constituting the power generator, reduce costs, and quickly find and recover from abnormalities.

  As a technology for detecting an abnormality relating to a solar power generation device, solar power management is possible for each solar cell module connected in series (hereinafter referred to as a “string array”) so that identification information and power generation amount data can be stored. A technology of a photovoltaic system is disclosed (Japanese Patent Laid-Open No. 2009-64809). Further, a technique is disclosed in which any one of a plurality of string arrays is used as an index string array and an abnormality is detected as compared with other string arrays (Japanese Patent Laid-Open No. 2008-271893). According to these technologies, a large number of detection units are required to detect and store the power generation amount data for each string array, the wiring of the string array becomes complicated, and abnormalities may occur in the detection unit itself. There was sex.

  In addition, a technology is disclosed in which a weather condition is determined from an accumulated power generation amount and an assumed power generation amount based on measured power generation, and an abnormality of the photovoltaic power generation system is determined using the weather state as a determination factor (specialty). No. 2006-67738). Furthermore, this patent document introduces a technology that provides a pilot solar cell for determining weather conditions, obtains the predicted power generation amount by the electric power generated by the pilot solar cell, and detects an abnormality in comparison with the actual generated power. Yes.

  However, even with this technology, when the pilot solar cell and the solar cell to be judged are installed at a distance, it becomes difficult to detect an abnormality due to the difference in the weather at the installation location, There is a problem that it is necessary to increase the number of pilot solar cells, and that when an abnormality occurs in the pilot solar cells, erroneous determination is caused.

JP 2009-64809 A JP 2008-271893 A JP 2006-67738 A

  Now, in order to reduce the cost of the solar power generation device, in addition to reducing the number of parts constituting the power generation system and simplifying the mechanism of the solar power generation device, the functions required by different manufacturers are met. It is necessary to procure parts to configure a solar power generation device. However, until now, technology development has been advanced in which the same manufacturer consistently manufactures photovoltaic power generation elements to inverters and detects abnormalities in the photovoltaic power generation apparatus inside the apparatus.

  On the other hand, small-scale photovoltaic power generators for home use have a power generation capacity of 2 to 5 kilowatts, and are composed of about 2 to 8 sets of solar cell string arrays (hereinafter referred to as “arrays”). Has been. Thus, if the arrays are of the same size, if any of these arrays fails and power generation is disabled, 50% for two arrays, 8 arrays If so, a clear decline in power generation capacity of 12.5% is recognized.

  When an abnormality occurs in any of the residential solar power generation arrays, the rate of decrease in the power generation capacity is 10% or more as described above, which is a value that is easy to determine. For this reason, the ratio (hereinafter referred to as “reference ratio”) obtained by subtracting the minimum array area from the total array area included in the photovoltaic power generation apparatus and dividing the area by the total array area (hereinafter referred to as “reference ratio”). If the abnormality of the solar power generation apparatus is determined, the abnormality of the solar power generation apparatus can be determined without providing a detection unit for each individual array.

  These abnormalities in the array include slight damage accumulated on the surface of the solar cell panel when the array itself is damaged by scattered objects, when the wiring of the array is damaged, or when bird droppings or dead leaves stick to the solar cell panel. It may also occur when the power generation capacity of the entire solar cell panel is reduced, for example, when weeds are grown from the sand or when the power generation module of the solar power generation device is totally deteriorated. If abnormalities can be detected early, repair if the array itself is faulty, clean if the panel surface of the solar cell is dirty, and if the power generation capacity decreases due to the construction of a nearby building, It is possible to respond to abnormal situations such as changing the installation location.

  In addition, although it is not an abnormality of the solar power generation device itself, when the solar power generation device is installed and a building that has a shadow on the solar power generation panel is constructed in the vicinity, the power generation capacity can be improved later. Abnormalities may occur. Such anomaly that occurs later is difficult to find with the technique of providing an anomaly detector in the string array disclosed in the above-mentioned prior patent document.

  In addition, the photovoltaic power generation devices are affected by the weather and the shade, and fluctuations in the power generation amount of the above-mentioned standard rate occur frequently during the day, and solar power generation is only possible if the power generation amount falls below the standard rate. It cannot be determined that the device is abnormal.

  However, when the sky above the area where the solar power generation apparatus is installed is covered with clouds, all the power generation capacities of the plurality of solar power generation apparatuses installed in that area are uniformly reduced. Then, on the display screen showing the installation position of the solar power generation device, if the power generation capabilities of the plurality of solar power generation devices are compared and compared under the same weather condition, the solar power generation in which an abnormality has occurred It is easy to discover the device.

  The problem to be solved by the present invention is to provide a photovoltaic power generation system capable of determining an abnormality of a photovoltaic power generation apparatus without providing an abnormality detection unit for each individual string array.

  A first invention of the present invention is a photovoltaic power generation including a plurality of photovoltaic power generation devices, and a central monitoring device that is connected to the photovoltaic power generation devices via communication means and monitors a power generation state of the photovoltaic power generation devices. A solar power generation system comprising: a plurality of solar power generation arrays configured by connecting a plurality of power generation strings formed of a plurality of solar cell modules connected in series in parallel; and A power measuring unit that measures generated power; and a power generating device communication unit that transmits and receives information about power generation including the generated power of the solar power generation device, wherein the central monitoring device relates to power generation transmitted by the power generating device communication unit A central monitoring device communication unit that receives information, an information processing unit that processes the generated power into a power generation index indicating a power generation capacity of each solar power generation device, and the power generation index of each solar power generation device It is characterized in that a central monitoring device display unit for displaying a position of each of the photovoltaic power generation apparatus is installed.

  According to 1st invention, the generated electric power measured by the electric power measurement part is converted into the electric power generation index which shows electric power generation capacity in the information processing part of a central monitoring apparatus. Then, the power generation indexes of the plurality of photovoltaic power generation devices are displayed at the installed positions on the central monitoring device display unit, and can be confirmed in comparison with the power generation indexes of the plurality of photovoltaic power generation devices installed nearby. The information on power generation includes an identification number of the solar power generation device, position information, generated power, information on the array, and the like. When the power generation capacity of a plurality of photovoltaic power generation devices installed in a specific area is reduced as a whole, it can be determined that the sky covers the area and the amount of solar radiation is small.

  However, when the power generation capacity of a specific solar power generation device is fluctuating as compared to the plurality of solar power generation devices displayed, it may be estimated that an abnormality has occurred only in that device. it can. As a result, even if a solar power generation device is configured by procuring parts satisfying the required functions from different manufacturers without providing a detection unit for each solar cell string or string array, it is determined that the solar power generation device is abnormal. become able to.

  A second invention of the present invention is the photovoltaic power generation system described in the first invention, wherein the information processing section includes a power generation information calculation means and a storage means, and the power generation index is the power generation index. For each solar power generation device, the information calculation means is obtained for each different unit time length based on the ratio of the unit time accumulated power generation amount obtained by integrating the generated power obtained by the power measurement unit to the assumed power generation capacity, The storage means stores the assumed power generation capacity and map information of each photovoltaic power generation device, and stores the power generation index, and the central monitoring device display unit displays the power generation index for each unit time length. Is capable of being displayed.

  In the second invention of the present invention, the assumed power generation capacity indicates the maximum power generation capacity per unit time that can be generated by an array in a normal state in fine weather, and the map information indicates that the solar power generation apparatus is installed. It is the information which shows the place. The power generation index is a ratio of the amount of generated power per unit time length to the assumed power generation capacity, and indicates how much power generation capacity was exhibited with respect to the maximum power generation capacity that can be generated per unit time length.

  Here, the unit time length means a time length in units of a period such as one hour, one day, one week, one month, one year, or the like. However, this may be changed and applied. The unit time may be the starting point of power generation, or the unit time may be started with each zero as the starting point. By changing the unit time length and displaying the power generation index, the power generation capacity in different time segments can be determined. Thereby, even if the fluctuation | variation of sunlight is large in a short time, the influence of sunlight can be reduced by lengthening unit time, and the several photovoltaic power generation apparatus installed nearby can be contrasted.

  A third invention of the present invention is the solar power generation system described in the second invention, wherein the information processing unit further includes an input unit and a site confirmation necessity determination unit, and the field confirmation necessity In the determination means, the determination value is determined for each of the plurality of unit time lengths, with a power generation index for each of the plurality of different unit time lengths for each photovoltaic power generation apparatus as a determination value corresponding to the power generation index for the previous year. When each is outside the predetermined determination range, it is determined that it is necessary to confirm the site, and the photovoltaic power generation device is confirmed by confirming the local situation of the photovoltaic power generation device that is out of the determination range. When it is necessary to correct the assumed power generation capacity, a solar power generation array and its time zone that are affected by a shadow are later input by the input means, and the power generation information calculation means The shadow Hibiki is acquired it reflected has been corrected assumed power generation capacity, is characterized in that to change the correction assumed power generation capacity from the assumed power generation capacity.

  According to the third aspect of the invention, the influence of construction or demolition of a building whose shadow has been increased or decreased in the solar cell array is reflected in the assumed power generation capacity of the solar power generation device. Increasing the predetermined determination range reduces the number of abnormality determinations, and narrowing the predetermined determination range increases the number of abnormality determinations.

  In the third invention, in the local confirmation necessity determination means, the power generation index acquired with a plurality of different lengths such as hourly, daily, weekly, monthly, etc., as the unit time length, By comparing with the index in order, it is determined whether or not each is out of a predetermined range. This eliminates the effects of weather fluctuations that occur every day even if it is out of the judgment criteria range on a daily basis, and even on a monthly basis even if it is outside the judgment criteria range on a weekly basis. By making a determination in step (2), the influence of the weather is eliminated, and errors in determining whether or not on-site inspection is necessary are reduced. In addition, by determining in order of day unit, week unit, and month unit, it is possible to determine which day the subsequent influence occurs. In addition, by acquiring the power generation index in units of time and confirming the fluctuation of the power generation index, it is possible to efficiently confirm the subsequent effects on the array locally.

  In addition, when the influence of the shadow after the solar power generation device is confirmed, the array and time zone affected by the shadow are input by the input means to calculate the power generation information of the information processing unit. The corrected assumed power generation capacity is acquired by means. Then, the assumed power generation capacity is changed to the corrected assumed power generation capacity. As a result, the power generation index of the solar power generation apparatus that is subsequently affected by the shade can be compared with the power generation index of other solar power generation apparatuses.

  4th invention of this invention is a solar power generation system described in 2nd or 3rd invention, Comprising: The said information processing part is a group which comprises the 1st group containing a several solar power generation device. The storage means stores a unique abnormality determination value of each photovoltaic power generation device, and the power generation information calculation means includes a plurality of suns included in the first group. The first abnormality based on a first index that is a standard value of the power generation index of the unit time length of the photovoltaic power generation apparatus and a ratio of the power generation index of each photovoltaic power generation apparatus included in the first group to the first index A determination value is acquired, and the first abnormality determination means compares the first abnormality determination value with the inherent abnormality determination value to determine the possibility of abnormality of each photovoltaic power generation apparatus, and the possibility of abnormality. A solar power generation device with , The central monitoring device display unit is characterized to be abnormal may see.

  According to the fourth aspect of the invention, the possibility of abnormality is determined by comparing the photovoltaic power generation device with the power generation status of other solar power generation devices installed nearby. The first group configuration includes a plurality of photovoltaic power generation devices provided nearby. Also, the inherent abnormality determination value is preferably a number close to the ratio of the area obtained by subtracting the smallest array area from the entire array area to the total of all the array areas, and larger than that. The power generation index may be any power generation index of one hour, one day, one week, or one month.

  Further, the first index that is a standard value may be an average value of all the photovoltaic power generation devices belonging to the group, or may be an average value of intermediate values excluding large and small power generation indexes in the group. When the number of photovoltaic power generation devices included in the group is small, it is preferable to set the average value except for the smallest photovoltaic power generation device.

  When the first abnormality determination value is smaller than the inherent abnormality determination value, there is a possibility that any one of the arrays is not generating power or there is an abnormality that reduces the power generation capacity in any part of the solar power generation device. Can be judged. This makes it possible to compare a plurality of photovoltaic power generation devices installed in the area without being affected by the weather, and determine the possibility of abnormality of the photovoltaic power generation devices included in the group be able to.

  5th invention of this invention is a solar power generation system described in 4th invention, Comprising: In the said information processing part, the said group structure means contains the said specific apparatus, 4th invention is described. A second group is configured to include a solar power generation device different from the solar power generation device, and the power generation information calculation means uses the unit time length power generation index standard of the plurality of solar power generation devices included in the second group. A second abnormality determination value is acquired based on a second index that is a value and a ratio of the power generation index of the specific device to the second index, and the second abnormality determination means obtains the second abnormality determination value and the unique An abnormality determination value is compared to determine the occurrence of an abnormality in the specific device, and an abnormality occurrence display is displayed on the central monitoring device display unit.

  According to the fifth invention, for the specific device according to the fourth invention, the second group configuration different from the first group is used to determine whether there is an abnormality as in the fourth invention, and the second group configuration If it is also determined that there is an abnormality, the occurrence of abnormality is determined. The second index which is a standard value may be an average value of all the photovoltaic power generation devices belonging to the second group, or may be an average value of intermediate values excluding a large power generation index and a small power generation index in the second group. . When the number of photovoltaic power generation devices included in the second group is small, it is preferable to set the average value except for the smallest photovoltaic power generation device.

  Here, it is preferable that the first group configuration and the second group configuration are configured with different policies. For example, the first group is a wide range in the horizontal direction on the screen, and the second group is a wide range in the vertical direction on the screen. If the first group is a narrow range, the second group may be a wide range. Thereby, the accuracy of abnormality determination is improved, and the abnormality occurrence display can be reliable.

  A sixth invention of the present invention is the photovoltaic power generation system described in the third invention, wherein any one of the photovoltaic power generation devices included in the system includes the power generation index as the communication with the central monitoring device. A power generation state display device including a display device communication unit that receives the power generation index and a display device display unit that displays the power generation index is included.

  According to the sixth aspect, the power generation index is displayed on the power generation state display device included on the solar power generation device side. As a result, the person who manages the power generation state display device can determine the state of the power generation state at the installation location of the solar power generation device under the current weather conditions.

  7th invention of this invention is a solar power generation system described in 4th invention, Comprising: In any of the said solar power generation devices contained in this system, a display apparatus communication part and a display apparatus display part The display device communication unit receives information from the central monitoring device communication unit that it is the specific device, and the display device display unit displays the abnormality possibility display. It is characterized by being displayed.

  According to the seventh aspect of the invention, the power generation state display device displays that there is a possibility of abnormality. Thereby, the person who manages the power generation state display device can know the possibility of abnormality of the solar power generation device at the installation location of the solar power generation device.

  An eighth aspect of the present invention is the solar power generation system described in the fifth aspect, wherein any one of the solar power generation devices included in the system includes a display device communication unit and a display device display unit. The display device communication unit receives the abnormality occurrence determination information from the central monitoring device communication unit, and the display unit display unit displays the abnormality occurrence display. It is characterized by that.

  According to the eighth aspect of the invention, the occurrence of abnormality is displayed on the power generation state display device. As a result, the person who manages the power generation status display device knows that an abnormality has occurred at the location where the solar power generation device is installed, and immediately disconnects the solar power generation device from the commercial power system to avoid affecting the power distribution system. it can.

According to 1st invention of this invention, even if it does not provide a detection part for every solar cell string or string array, abnormality of a solar power generation device can be judged. As a result, not only solar power generators manufactured consistently by one manufacturer, but also solar power generators can be configured by procuring simplified parts that meet the required functions from different manufacturers. It becomes possible to judge abnormality of the photovoltaic power generation apparatus.
According to the second aspect of the present invention, it is easy to find a solar power generation device having a reduced power generation capacity by comparing a plurality of solar power generation devices installed nearby with different unit time lengths.

According to the third aspect of the present invention, it is possible to determine whether or not it is necessary to correct the assumed power generation capacity of the solar power generation apparatus that has been affected by the shadow. In addition, by correcting the assumed power generation capacity, the power generation index of a solar power generation apparatus that is subsequently affected by the shadow can be compared with the power generation index of other solar power generation apparatuses on a map.
According to the fourth aspect of the invention, it can be determined that there is a possibility of abnormality in the solar power generation device.
According to the fifth aspect of the invention, the accuracy of abnormality determination is improved and the abnormality occurrence display is reliable.

According to the sixth aspect, it is possible to determine what the power generation state is under the weather condition of the place where the photovoltaic power generation apparatus is installed.
According to the seventh aspect, the possibility of abnormality of the solar power generation device can be known at the installation location of the solar power generation device.
According to the eighth aspect of the invention, it is possible to know the occurrence of an abnormality at the place where the solar power generation apparatus is installed, and to quickly disconnect the solar power generation apparatus from the commercial power system.

Example of multiple houses with solar power generation equipment (Example 1) Configuration diagram of solar power generation system (Example 1) Central monitoring device block diagram (Example 1) Power generation state display device block diagram (Example 1) Map information of houses with solar power generators (Example 1) Power generation capacity correction flow chart (Example 1) Abnormality possibility flow chart (Example 1) Abnormality occurrence determination flowchart (Example 1) Explanatory drawing of the group structure of abnormality determination (Example 1) Explanatory drawing of the group structure of abnormality determination (Example 2)

[Example 1]
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same.

  FIG. 1 is a diagram showing an image of a plurality of houses provided with the solar power generation apparatus according to the present embodiment. The photovoltaic power generation apparatus according to the present embodiment is installed on the roofs of a plurality of houses 001, 002, 003. Nearby, there is also a house 000 that does not have a solar power generation device installed.

  In the house 001, a solar power generation device 21 including three sets of arrays 211, 212, and 213 is installed. Four sets of arrays are installed in the house 002 and the house 003. As power generation elements used in arrays, various types of power generation elements such as single crystal silicon, polycrystalline silicon, compound, and organic have been developed, and the conversion efficiency for converting solar energy into electricity Depending on the type, those having a performance different from about 18% to 4% are used.

  The power generation capacity of the solar power generation devices 21, 22, 23 of each house is the conversion efficiency of the power generation element, the area of the array, the orientation and inclination angle of the roof on which the array is installed, the element temperature, the conversion efficiency of the power inverter, etc. Determined by the elements of The orientation of the roof and the inclination angle will be described. When the conversion efficiency when the array is directed southward and the inclination angle is 30 degrees is 100, the conversion efficiency is 78 when the array is directed east or west and the inclination angle is 40 degrees. .9. Even if the element temperature rises, the conversion efficiency decreases to about 20%, and the power inverter also decreases the conversion efficiency to several%. Furthermore, the conversion efficiency varies depending on the sunshine conditions. The assumed power generation capacity is determined according to the parameters affecting the conversion efficiency described above.

  FIG. 2 is a diagram showing a configuration of the photovoltaic power generation system according to the present embodiment. The photovoltaic power generation system according to the present embodiment includes a plurality of photovoltaic power generation devices ID001 (hereinafter, the photovoltaic power generation devices are identified and represented only by ID and numbers), ID002, ID00m, and the central monitoring device 80. It is made up of. ID001 includes a plurality of arrays 211 in which a plurality of power generation strings 110 in which solar cell modules 100 that are power generation elements are connected in series are connected in parallel, a power inverter 31, a power measurement unit 41, and a power generation device communication unit 51. Contains.

  The DC power generated by the array 211 is collected by a DC current collector (not shown), converted from DC power to AC power by the power inverter 31, and linked to a distribution system including commercial power 60. , Supplied to loads 71 and 72 of the distribution system in the house.

  The power inverter 31 is provided with a power measurement unit 41 that measures the generated power and a power generation device communication unit 51. The power measuring unit 41 measures the generated power converted by the power inverter 31. The power generation device communication unit 51 acquires the generated power measured by the power measurement unit 41 and transmits it to the central monitoring device 80. A communication protocol with the central monitoring device 80 is not particularly limited, and Web communication is performed using an Internet protocol as an example. The power measurement unit 41 and the power generation device communication unit 51 may be included in the power inverter 31.

  In ID002, a power generation state display device 90 is attached to the power inverter 31. The generated power transmitted from the power generation device communication unit 51 is transmitted to the central monitoring device 80 via the power generation state display device 90.

  The configuration of the central monitoring device 80 will be described with reference to FIG. The central monitoring device 80 includes a central monitoring device communication unit 81, a central monitoring device display unit 82, and an information processing unit 83. The central monitoring device communication unit 81 receives the amount of generated power transmitted from the power generation device communication unit 51 or the power generation state display device 90 and transmits information related to the power generation index and power generation abnormality to the power generation state display device 90. The central monitoring device display unit 82 displays the power generation index together with the map information. The information processing unit 83 is equipped with a microcomputer, and includes a central processing unit (CPU), a storage device (RAM, ROM), and a keyboard.

  Here, with reference to FIG. 4, the structure of the electric power generation state display apparatus 90 is demonstrated. The power generation state display device 90 includes a display device communication unit 91 and a display device display unit 92. The display device communication unit 91 transmits the generated power received from the power generation device communication unit 51 to the central monitoring device communication unit 81, and receives information related to the power generation index and power generation abnormality from the central monitoring device communication unit 81. The display device display unit 92 can display at least information related to power generation abnormality received from the central monitoring device communication unit 81.

  Note that either the power generation device communication unit 51 or the display device communication unit 92 is omitted, and the provided communication unit (51 or 92) acquires the generated power from the power measurement unit 41, and the communication unit (51 Or 92) may communicate with the central monitoring device communication unit 81.

  The information processing unit 83 will be specifically described with reference to FIG. The information processing unit 83 includes a storage unit 831, a power generation information calculation unit 832, an input unit 833, a group configuration unit 834, and a determination unit 835.

  The storage unit 831 includes the RAM and the ROM. In the RAM, according to the identification number of the solar power generation device in advance, the conversion efficiency of the power generation elements constituting each array, the area of each array, the power generation parameters such as the azimuth and inclination in which each array is installed, The assumed power generation capacity in fine weather, the map information indicating the longitude and latitude where the solar power generation apparatus is installed, the generated power at each time, and the power generation index calculated by the power generation information calculation means 832 are stored in the ROM. A program executed by the central processing unit is stored.

  The power generation information calculation means 832 is processed by the central processing unit. The power generation information calculation means 832 calculates the integrated power generation amount per unit time length based on the acquired power generation amount. Here, the unit time length means the length of time in units of one hour, one day, one week, one month, and one year. Further, the integrated power generation amount per unit time length is divided by the assumed power generation capacity to obtain a power generation index per unit time length indicating the power generation capacity.

  In addition, when the influence of other shades appears on the solar power generation device later, the power generation information calculation unit 832 acquires the corrected assumed power generation capacity.

  In addition, the power generation information calculation means 832 uses the first index and the first index indicating the standard power generation capacity of the group based on the power generation indexes of a plurality of solar power generation devices configured in the first group or the second group described later. Two indices are obtained. When the number of grouped photovoltaic power generation devices is small, the first index or the second index is an average value excluding the minimum power generation index. Moreover, when there are many photovoltaic power generation apparatuses comprised in a group, it is good also as an average value of all the said power generation indexes. In addition, for each power generation index of each photovoltaic power generation apparatus, a first abnormality determination value is acquired based on a ratio with respect to the first index and a ratio with respect to the second index.

  In the input means 833, the initial generation capacity such as the identification number, the map information, the array area, and the like, the array area and time that are affected by the shadow, etc. Information for correcting the initial information is input.

  The group constituting unit 834 constitutes a group including at least three or more solar power generation devices. In the group configuration means, a plurality of photovoltaic power generation devices displayed based on the map information are grouped based on the distance and position between them.

  In the determination unit 835, the determination program stored in the storage unit 831 is executed by the central processing unit, and it is necessary to confirm the site of each photovoltaic power generation apparatus, or there is a possibility of abnormality. It is determined whether or not an abnormality has occurred.

  Next, processing of the present invention will be described with reference to a flowchart. First, a case where correction of the assumed power generation capacity is determined will be described. When a large number of solar power generation devices are installed, it is considered that some of these solar power generation devices are affected by the shadows of buildings that were constructed later. In addition, buildings that have been shaded may be removed, and the power generation environment may be improved later.

  However, it is difficult to routinely check the situation where the solar power generation apparatus installed on the roof receives sunlight. Therefore, although it is a posteriori, such a state is discovered early, and when an abnormality has occurred in the solar power generation device, it is discovered and the assumed power generation capacity is corrected and updated.

  More specifically, for example, in the house 002 of FIG. 1, power generation is not possible when there is no sunlight in the array 224 due to the influence of a building constructed in the vicinity and power generation abnormality has occurred due to insufficient sunlight. The fact that the array 224 cannot generate power during a predetermined time period is reflected in the predicted power generation capacity of the house 002.

  With reference to the flowchart of FIG. 5, the correction flow in the case of correcting the initial value of the assumed power generation capacity will be specifically described. The correction process is started after the photovoltaic power generation apparatus finishes power generation due to sunset.

  First, obtain a daily power generation index. The daily power generation index is obtained by integrating the generated power at each time stored in the storage means of the information processing unit (step S310). In addition, the daily power generation index is stored in the storage unit. Although omitted in this flow, the daily power generation index may be obtained after obtaining the hourly power generation index.

  Next, the power generation index is divided by the power generation index for the corresponding day of the previous year stored in the storage unit to obtain a determination value for each day, and it is determined whether or not the determination reference value is out of the range (step S312). . The determination reference value is, for example, “0.7 or more and 1.3 or less”. If this criterion value is reduced, it becomes more susceptible to the influence of the weather, so frequent examination is necessary.If this criterion value is increased, it becomes less susceptible to the weather, but a small abnormality is found. Becomes difficult. Here, when the determination value falls within the range of the determination criterion, the determination is terminated with no consideration of abnormality. If the determination value is outside the determination criterion range, the process proceeds to step S314.

  In step S314, the daily power generation index stored in the storage unit is integrated, and the weekly power generation index is acquired and stored in the storage unit (step S314).

  Next, a determination value is obtained by dividing the weekly power generation index by the corresponding weekly power generation index stored in the storage unit, and it is determined whether the determination reference value is out of the range (step S316). The weekly determination reference value is also set to “0.7 or more and 1.3 or less”, for example. Even if it is out of the range of the judgment standard on a daily basis, by making a judgment on a weekly basis, it becomes less affected by the weather of the day, and errors in the necessity of local confirmation are reduced. If the weekly first power generation index is outside the determination range, the process proceeds to step S318. Here, when the determination value falls within the range of the determination criterion, the determination of abnormality is unnecessary and the determination is terminated.

  In step S318, the weekly power generation index stored in the storage unit is integrated, and the monthly power generation index is acquired and stored in the storage unit (step S318).

  Next, the power generation index in units of months is divided by the power generation index of the corresponding month stored in the storage unit in the previous year to obtain a determination value, and it is determined whether or not it is outside the range of the determination reference value (step S320). . The monthly reference value is also set to “0.7 or more and 1.3 or less”, for example. Even if it is out of the range of the determination criteria on a weekly basis, since the influence of the weather is reduced by making the determination on a monthly basis, the accuracy of the determination of the necessity of field inspection is improved. If the determination value is within the determination range on a monthly basis, the correction process ends. If the determination value is out of the determination criterion range on a monthly basis, the process proceeds to step S322.

  In step S322, the site is visually confirmed and checked for the presence or absence of the cause of the subsequent lack of sunlight and the abnormality of the power generation apparatus. Specifically, whether there is a newly constructed building around the solar power generation device, whether there is a new building if there is a new building, whether the array is affected by the shadow and its time The band, the contamination of the array surface, and the like are confirmed, and if correction of the assumed power generation capacity of the photovoltaic power generation apparatus is necessary, the process proceeds to step S324, and if correction is not necessary, the correction process is terminated.

  Next, information for reflecting the local situation such as the array and time zone in which the influence of the shadow is newly reflected on the assumed power generation capacity is input by the input means 833 (step S324). Next, the power generation information calculation means 834 obtains a correction value of the assumed power generation capacity according to the local situation such as the array and time zone that are newly affected by the shadow (step S326). Then, the assumed power generation capacity is replaced with the assumed power generation capacity before correction stored in the storage unit (step S328), and the correction process is terminated.

  Next, with reference to FIG. 6 to FIG. 9, the abnormality determination operation of the photovoltaic power generation system of the present invention will be specifically described. 6A shows the display state of the central monitoring device display unit 82 when the weather is cloudy, and FIG. 6B shows the display state of the central monitoring device display unit 82 when the weather is clear. Yes. FIG. 7 shows a flow for determining whether or not there is a possibility of abnormality, and FIG. 8 shows a flow for determining whether or not an abnormality has occurred.

  In FIG. 6, the power generation index of each photovoltaic power generation device is displayed on the display screen in a circular display having a size corresponding to the power generation index at the position of latitude / longitude installed according to the identification number. .

  In FIG. 6A, any circle display indicating the power generation index of each photovoltaic power generation apparatus is displayed smaller than that in FIG. 6B, indicating that the weather is cloudy. However, in both FIG. 6A and FIG. 6B, ID002 is displayed smaller than the surrounding ID001, ID003, ID004, and ID005, and ID002 generates sufficient power for the assumed power generation capacity regardless of the weather conditions. It can be judged that the ability is not being demonstrated.

  Here, in the cloudy area, for example, there is ID002, and a flow for determining abnormality of ID002 will be described.

  In the flow for determining whether or not there is a possibility of abnormality, abnormality determination is started periodically or at an arbitrary time. In step S350, ID002 that has been displayed in a small circle is selected as a determination target. ID 002 is selected by inputting the identification number of the photovoltaic power generation device with the input means 833. It is also possible to program all the photovoltaic power generation devices displayed on the screen so that they are sequentially determined.

  Next, in the group configuration means 834 included in the information processing unit 83, ID003 and ID004 that are close to each other in the vertical direction on the screen are selected as targets for the first group configuration, and the first group configuration including ID002 is performed. (Step S352) (see FIG. 9).

  Next, in the power generation information calculation means 832 included in the information processing section 83, the power generation index in units of time ID002 to ID004 is integrated with the generated power at each time stored in the storage means 831 of the information processing section. The first index that is the average value of the power generation indexes of ID003 and ID004 is calculated (step S354). Here, for example, although ID003 and ID004 exhibit the power generation capability satisfactorily, the power generation index is 0.7 because they are in the cloudy area. Further, ID002 has a power generation index of, for example, 0.55 because an abnormality has occurred in one of the four arrays. In the case of this embodiment, since the number of power generation devices constituting the group is three and the number is small, the average value excluding the minimum ID002 is used as the first index.

  Next, the power generation index of ID002 is divided by the first index to obtain a first abnormality determination value (here, 0.79) (step S356).

  Next, the unique abnormality determination value of ID002 is read from the storage unit (step S358). Here, the specific abnormality determination value will be specifically described. For example, the total area of the ID002 array is 20 square meters, and the smallest array area is 5 square meters. The unique abnormality determination value of ID002 is a value 0.8 obtained by subtracting the area of the smallest array from the total area of the array and dividing it by the total area of the array and rounding it up to one decimal place. .

  Next, the first abnormality determination value (0.79) of ID002 is compared with the inherent abnormality determination value (0.8). The first abnormality determination value is smaller than the inherent abnormality determination value, and it is determined that there is a possibility of power generation abnormality in any of the arrays (step S360), and the process proceeds to step S362. Here, when the first abnormality determination value is larger than the inherent abnormality determination value, it is determined that there is no abnormality, and the abnormality possibility determination flow ends.

  In step S362, the possibility of abnormality of the photovoltaic power generator is displayed on the screen of the central monitoring device display unit 82 at the position of the specific device based on the identification number. Further, when the power generation state display device 90 is provided, the abnormality possibility information is transmitted from the central monitoring device communication unit 81 to the display device communication unit 91 together with the identification number of the specific device, and the display device display unit 92 is displayed. Is also displayed, and the abnormality possibility determination flow ends.

  If it is determined that there is a possibility of abnormality, an abnormality occurrence determination is performed next. The operation for determining the occurrence of abnormality will be described with reference to the flowchart of FIG. The group constituting unit waits for the transmission of the abnormality possibility determination information (step S400).

  When the abnormality possibility information is received and acquired together with the identification number of the specific device, a second group including the specific device and including the power generation device near the specific device is configured (step S402). Here, ID002 which is a specific device and ID001 and ID005 which are adjacent in the horizontal direction on the screen are selected as the solar power generation devices included in the second group, and the second group is configured (see FIG. 9). ID001 and ID005 are selected based on the direction and distance from the specific device.

  Next, in the power generation information calculation means 832 included in the information processing section 83, the power generation indexes in units of time of ID001 and ID005 are integrated with the generated power at each time stored in the storage means 831 of the information processing section. And the second index that is the average value of ID001 and ID005 is calculated (step S404). Here, ID001 and ID005 are 0.7, similar to the above-described ID003 and ID004. Further, the power generation index of ID002 is 0.55 as described above because an abnormality has occurred in one of the four arrays.

  Next, the power generation index of ID002 is divided by the second index to obtain a second abnormality determination value (here, 0.79) (step S406).

  Now, in the abnormality occurrence determination flow, the inherent abnormality determination value has already been read in the abnormality possibility determination flow, so the already-read inherent abnormality determination value (0.8) and the second abnormality determination of ID002 are described. Compare the value (0.79). Since the second abnormality determination value is smaller than the inherent abnormality determination value, it is determined that there is a power generation abnormality in the specific device (step S410), and the process proceeds to step S412. Here, when the second abnormality determination value is larger than the inherent abnormality determination value, it is determined that there is no abnormality, and the abnormality possibility determination flow ends.

  In step S412, the abnormality occurrence display of the photovoltaic power generation device is displayed on the screen of the central monitoring device display unit 82 at the position of the specific device based on the identification number. In addition, when the power generation state display device 90 is provided, the abnormality occurrence information is transmitted from the central monitoring device communication unit 81 to the display device communication unit 91 of the specific device together with the identification number of the specific device. The display is also made on the display device display unit 92, and the abnormality occurrence determination operation ends. The abnormality occurrence display may be any display such as character information, blink information, and sound information.

  Although the above description has been given in a state where the weather is cloudy (see FIG. 6A), the same applies to a state where the weather is clear (see FIG. 6B). In other words, the power generation index of ID001, ID003, ID004, ID005 where no abnormality has occurred and the power generation index of ID002 where abnormality has occurred are the values when the weather is clear when the weather is cloudy. The ratio is the same for each value. Thereby, abnormality of a solar power generation device can be determined with the said flow irrespective of the weather. In addition, when the abnormality discovered by the flow which determines abnormality is the influence of the building constructed | assembled lately, it is good to correct | amend assumption power generation capability by step S324 to step S328 of the correction | amendment flow mentioned above.

[Second Embodiment]
In the second embodiment, an embodiment in the case of another group configuration will be described with reference to FIG. In the second embodiment, when it is determined that there is a possibility of abnormality in ID002 due to the first group configuration of ID002, ID003, and ID004, the specific device ID002 is included, and many surrounding ID006 to ID012 are included. To form a second group. Since the flow after acquisition of the power generation index of each photovoltaic power generation apparatus is the same as that of the first embodiment, the description thereof is omitted. By making an abnormality determination including a large number of photovoltaic power generation apparatuses, the influence of the weather in the surrounding sky is not biased, and an erroneous determination result is suppressed.

[Others]
In the above embodiment, the power generation device for a house with a small number of arrays has been described as an example, but the present invention is not limited to the home use. In the case of a large-scale power generation device with a large number of arrays, as described above, the solar power generation device is based on a reference ratio obtained by dividing the total area of the array excluding the minimum array area by the total area of the array. What is necessary is just to acquire the specific abnormality determination value.
In the above embodiment, the abnormality that any of the arrays becomes unable to generate power has been described. However, the present invention can also be applied to cases where an abnormality in which the power generation element deteriorates and the power generation capacity decreases as a whole is recognized. . In that case, the reference ratio may be replaced with a value for determining deterioration, for example, 0.9.

In the above embodiment, the generated power measured by the power generation measuring unit is transmitted to the central monitoring device, and the integrated power generation amount is calculated by the central monitoring device. The integrated power generation amount including the means may be transmitted to the central monitoring device by the power generation device communication unit.
-In above-mentioned Example, although the 1st parameter | index and the 2nd parameter | index were made into the average value of the power generation index | exponent of the solar power generation device contained in a group, it is not limited to an average value. When the number of photovoltaic power generation devices included in the group is large, an abnormality may be determined based on whether a deviation value of each photovoltaic power generation device is obtained and within a predetermined range.

The present invention is naturally applied to a case where parts are procured from different parts manufacturers to configure a photovoltaic power generation system, and also to a case where the power generation element to the central monitoring apparatus are manufactured consistently.
-It should be thought that embodiment disclosed this time is an illustration and restrictive at no points. The technical scope of the present invention is shown not by the above description but by the scope of claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

000,001,002,003 ... House,
211, 212, 213, 221, 222, 223, 224, 231, 232, 233, 234... Power generation array, 21, 22, 23.
100 ... power generation module, 110 ... power generation string, 31 ... power inverter,
41 ... Power measurement unit, 51 ... Power generation device communication unit, 60 ... Commercial power,
71, 72 ... Power generation load, 80 ... Central monitoring device, 90 ... Power generation state display device,
81 ... Central monitoring device communication unit, 82 ... Central monitoring device display unit, 83 ... Information processing unit,
831 ... Storage means, 832 ... Power generation information calculation means, 833 ... Input means,
834 ... Group configuration means, 835 ... determination means, 91 ... display device communication section,
92 ... Display device display section

Claims (8)

A solar power generation system including a plurality of solar power generation devices, and a central monitoring device that is connected to the solar power generation devices via communication means and monitors the power generation state of the solar power generation devices,
The solar power generation device measures a plurality of solar power generation arrays configured by connecting a plurality of power generation strings made up of a plurality of solar cell modules connected in series in parallel, and power generated by the solar power generation device. A power measurement unit, and a power generation device communication unit that transmits and receives information on power generation including the generated power of the solar power generation device,
The central monitoring device includes a central monitoring device communication unit that receives information about power generation transmitted by the power generation device communication unit, and an information processing unit that processes the generated power into a power generation index indicating a power generation capability of each solar power generation device. And a central monitoring device display unit for displaying the power generation index of each solar power generation device at a position where each solar power generation device is installed,
A solar power generation system characterized by that. The information processing unit includes power generation information calculation means and storage means,
The power generation index is a ratio of the unit time integrated power generation amount obtained by integrating the generated power acquired by the power measurement unit for each solar power generation device for each different unit time length by the power generation information calculation unit to the assumed power generation capacity. Based on
The storage means stores the assumed power generation capacity and map information of each photovoltaic power generation apparatus, and stores the power generation index.
In the central monitoring device display unit, the power generation index can be displayed for each unit time length,
The photovoltaic power generation system according to claim 1. The information processing unit further includes an input unit and a site confirmation necessity determination unit,
In the on-site confirmation necessity determination means, a power generation index for each of a plurality of different unit time lengths for each photovoltaic power generation device is used as a determination value as a ratio with respect to the power generation index for the previous year. In the case where each of the determination values is outside the predetermined determination range, it is determined that it is necessary to confirm the site,
When it is necessary to correct the assumed power generation capacity of the solar power generation device by checking the local situation of the solar power generation device that is out of the determination range,
In the input means, the photovoltaic power generation array and its time zone that are affected by the shadow are input later,
The corrected estimated power generation capacity reflecting the influence of the shade is acquired by the power generation information calculation means, and is changed from the assumed power generation capacity to the corrected estimated power generation capacity.
The photovoltaic power generation system according to claim 2. The information processing unit includes a group configuration unit that configures a first group including a plurality of photovoltaic power generation devices, and a first abnormality determination unit.
The storage means stores a unique abnormality determination value of each photovoltaic power generation device,
In the power generation information calculation means, a first index that is a standard value of the power generation index of the unit time length of the plurality of solar power generation devices included in the first group, and each solar power generation device included in the first group And a first abnormality determination value based on a ratio of the power generation index to the first index,
In the first abnormality determination means, the first abnormality determination value and the inherent abnormality determination value are compared, the possibility of abnormality of each solar power generation apparatus is determined, and a solar power generation apparatus having a possibility of abnormality is determined. A specific device,
The central monitoring device display unit displays a possibility of abnormality.
The photovoltaic power generation system according to claim 2 or claim 3, wherein In the information processing unit, the group configuration unit includes the specific device, includes a solar power generation device different from the solar power generation device according to claim 4, and configures a second group,
In the power generation information calculation means, a second index that is a standard value of the power generation index of the unit time length of the plurality of photovoltaic power generation devices included in the second group, and a ratio of the power generation index of the specific device to the second index And the second abnormality determination value is acquired based on
In the second abnormality determination means, the second abnormality determination value and the inherent abnormality determination value are compared, an abnormality occurrence of the specific device is determined, and an abnormality occurrence display is displayed on the central monitoring device display unit.
The photovoltaic power generation system according to claim 4. Any of the photovoltaic power generation devices included in the photovoltaic power generation system includes a display device communication unit that receives the power generation index from the central monitoring device communication unit, and a display device display unit that displays the power generation index. Power generation status display device included,
A photovoltaic power generation system according to claim 3. Any of the photovoltaic power generation devices included in the photovoltaic power generation system includes a power generation state display device including a display device communication unit and a display device display unit, and the display device communication unit is configured to communicate with the central monitoring device. Information indicating that the specific device is received from the display unit, and the display device display unit displays the abnormality possibility display.
The photovoltaic power generation system according to claim 4. Any of the photovoltaic power generation devices included in the photovoltaic power generation system includes a power generation state display device including a display device communication unit and a display device display unit, and the display device communication unit is configured to communicate with the central monitoring device. Receiving the information on the occurrence of abnormality from the unit, and the display unit displaying the abnormality occurrence display,
The photovoltaic power generation system according to claim 5.