JP4795252B2 - Inverter - Google Patents

Abstract

A power conditioner provided can store running data safely even in case where a storage means fails. The power conditioner comprises a power conversion unit (31) for converting the DC power of a power source into an AC power, a measurement operation unit (32) for operating running data by measuring a parameter relating to the power conversion by the power conversion unit (31), first and second storage units (34 and 35) for storing the running data operated by the measurement operation unit, and a data write processing unit (33) for performing a processing to write the running data in the first and second storage units (34 and 35), whereby the running data is duplexed and stored.

Description

  The present invention relates to a power conditioner that converts DC power generated by a power generation source such as a solar battery into AC power. The present invention also relates to a display device used for a power conditioner.

  In a photovoltaic power generation system, DC power generated by a solar cell is converted into AC power by a power conditioner, and the power generated by grid connection with a commercial power supply is supplied to a load in a house or sold to the commercial power supply side. System. As a power conditioner used in this photovoltaic power generation system, a calculation means for calculating output data of the power conditioner for each arbitrarily set unit period, and output data for each unit time calculated by the calculation means are stored. Storage means, and output data for each unit time is displayed on a display means provided at a location different from the main body of the power conditioner connected to the main body of the power conditioner by a control line and a power line. The power conditioner which did is proposed (for example, refer patent document 1).

Japanese Patent Laid-Open No. 11-111984

  However, in the power conditioner described in Patent Document 1, when a failure or the like occurs in the storage unit that stores the output data for each unit period of the power conditioner, the output data for each unit period of the power conditioner can be stored. There is a problem that the data during the failure period of the storage means cannot be recorded.

  Moreover, since the display means in the power conditioner described in Patent Document 1 is provided separately from the main body of the power conditioner, the size thereof is not particularly limited. In such a display means, the size can be selected at the design stage according to the content to be displayed, but when the display means is provided in the main body of the power conditioner, the size is the main body of the power conditioner. The content displayed on the display means is also limited. For example, when a liquid crystal display device of 128 dots × 64 dots is provided as a display means in the main body of the inverter, if a graph is displayed on the display means, it becomes very small and difficult to see. In order to eliminate this difficulty, it is only possible to simplify the graph display such as omitting the scale to be attached to the horizontal axis and the vertical axis, but in this case, accurate information cannot be read from the graph display. There was a problem.

  The present invention has been made in view of the above, and an object thereof is to obtain a power conditioner that can safely store operation data such as output data of a power conditioner even when a failure occurs in a storage unit. To do. It is another object of the present invention to provide a display device that can read accurate information from the contents of a displayed graph even in display means that are limited by the size of the screen as provided in such a power conditioner. And

In order to achieve the above object, a power conditioner according to the present invention measures power conversion means for converting DC power of a power generation source into AC power, and parameters related to power conversion by the power conversion means to obtain operation data. Measurement calculation means for calculating, communication means for communicating with the information processing terminal, first storage means for storing operation data calculated by the measurement calculation means in a first data format, and the measurement calculation Second storage means for storing the operation data calculated by the means in a second data format that can be directly read by application software installed in the information processing terminal; and the first and second memories and a data write processing means for performing the writing operation data processing means, said data writing means, the operating data of the first data format While stored in the first storing means, by converting the operation data of the first data format into the second data format stored in said second storage means, said operating data in different data formats It is characterized by being duplicated and stored.

  According to the present invention, the first and second storage means are provided, and the operation data in the power generation system including the power conditioner is stored in each of the first and second storage means. Even if the storage of the operation data is not performed, the operation data is stored in the other storage means, the loss of the operation data is eliminated, and the reliability of the operation data storage becomes extremely high.

FIG. 1 is a block diagram showing a schematic configuration of a photovoltaic power generation system including a power conditioner according to the present invention. FIG. 2 is a block diagram schematically showing a schematic configuration of a photovoltaic power generation system including a power conditioner according to the present invention. FIG. 3A is a diagram illustrating an example of a front view of a power conditioner. 3-2 is a diagram illustrating an example of a mounting state of the second storage unit in the power conditioner of FIG. 3-1. FIG. 4 is a diagram illustrating an example of the structure of display screen data managed by the display processing unit. FIG. 5A is a diagram illustrating an example of a screen displayed on the display unit by the display processing unit. FIG. 5B is a diagram illustrating an example of a screen displayed on the display unit by the display processing unit. FIG. 5C is a diagram illustrating an example of a screen displayed on the display unit by the display processing unit. FIG. 5-4 is a diagram illustrating an example of a screen displayed on the display unit by the display processing unit. FIG. 5-5 is a diagram illustrating an example of a screen displayed on the display unit by the display processing unit. FIG. 5-6 is a diagram illustrating an example of a screen displayed on the display unit by the display processing unit.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Solar cell 20 Connection box 30 Power conditioner 31 Power conversion part 32 Measurement calculating part 33 Data writing process part 34 1st memory | storage part 35, 35a 2nd memory | storage part 36 Display part 37 Display process part 38 Display switching part 39 Mounting part 40 Distribution board 50 Commercial power supply (system)
51 Load

  Exemplary embodiments of a power conditioner and a display device according to the present invention are explained in detail below with reference to the accompanying drawings. In the following description, the case of a power conditioner in a solar power generation system using a solar cell as a power generation source will be described as an example. However, the power generation source only needs to generate DC power, for example, A fuel cell may be used.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing a schematic configuration of a photovoltaic power generation system including a power conditioner according to the present invention. The solar power generation system is installed on a roof of a house, etc., and receives solar light to generate DC power, and a junction box 20 that collects DC power generated by the solar battery 10 and prevents backflow. And the power conditioner 30 that converts the output power of the solar cell 10 from the connection box 20 into AC power, and the AC power from the power conditioner 30 is distributed to the load 51 and the commercial power source (system) 50 owned by the power company. And a distribution board 40.

  In the distribution board 40, a main breaker 41, an interconnection breaker 42, and a branch breaker 43 are accommodated. Electric power from the commercial power supply 50 is supplied into the house via the main breaker 41 and further supplied to each load 51 in the house via the branch breaker 43. Further, the output (generated power) of the power conditioner 30 is connected to a commercial power source (system) 50 via an interconnection breaker.

  The power conditioner 30 has a function of converting DC power generated in the solar cell 10 into AC power, measuring operation data such as power input to the power conditioner 30, and storing and displaying the data. The power conversion unit 31, the measurement calculation unit 32, the data write processing unit 33, the first storage unit 34, the second storage unit 35, the display unit 36, the display processing unit 37, and the display switching unit 38 are configured. .

  The power conversion unit 31 has a function of converting DC power from the connection box 20 into AC power and outputting the AC power to the distribution board 40.

  The measurement calculation unit 32 measures the input voltage (direct current), input current (direct current), output voltage (alternating current), output current (alternating current), output power (alternating current), etc. of the power conversion unit 31, and the measured output power. It has a function of obtaining operation data by calculating an output power amount (power generation amount) from (AC). For example, input voltage (direct current), input current (direct current), output voltage (alternating current), output current (alternating current), output power (alternating current) are measured every predetermined measurement time, and within an arbitrarily set unit period. Operation data is obtained by averaging the measured values, and for output power (power generation), the output power (alternating current) measured at a predetermined measurement time is integrated within an arbitrarily set unit period. The aggregated data is used as operation data. As the unit period to be totaled, for example, every minute, every hour, every day, every month, or every year can be set. The operation data also includes information related to the date and time when the operation data is acquired. The measurement calculation unit 32 outputs the calculated operation data to the data write processing unit 33.

  The data write processing unit 33 has a function of storing the operation data output by the measurement calculation unit 32 in both the first and second storage units 34 and 35.

  The first and second storage units 34 and 35 have a function of storing the operation data measured and calculated by the measurement calculation unit 32, and the stored contents are stored even when the power is turned off. It is configured by storage means such as a nonvolatile memory such as a memory or a magnetic storage device such as a hard disk drive. The first and second storage units 34 and 35 store operation data including the acquisition date and time obtained by the measurement calculation unit 32 described above. In addition to the operation data, it is provided in the vicinity of the installation position of the solar cell 10 or the operation state data such as operation / non-operation of the power conditioner 30 at the time of measurement, connection / non-connection, normal operation / abnormal stop, etc. Weather data such as outside air temperature and solar radiation intensity measured by a thermometer or a pyranometer (not shown) may be added to the operation data and stored. In addition, the first and second storage units 34 and 35 store operation data including the acquisition date and time, but other operation state data and weather data are stored in the first storage unit 34 or the second storage unit. Only one of the units 35 may be stored. In this way, by storing the operation data in both the first and second storage units 34 and 35, the operation data of the saved power conditioner 30 can be duplicated.

  The display unit 36 is configured by a display device such as a liquid crystal display or an organic EL (Electro Luminescence) display.

  The display processing unit 37 has a function of causing the display unit 36 to display the operation data stored in the first storage unit 34 or the second storage unit 35. For example, the display unit 36 has a function of displaying operation data such as the current output power amount (power generation amount) or displaying operation data for a predetermined period in a graph or a table format.

  The display switching unit 38 is an interface with a user such as an administrator or a user of the power conditioner 30 for switching contents to be displayed on the display unit 36, and is configured by buttons such as cursor keys, for example. The display switching unit 38 instructs the display processing unit 37 to switch display contents. For example, the input voltage (DC), input current (DC), output voltage (AC), and output current of the power conversion unit 31 are displayed. When displaying operation data such as (alternating current), output power (alternating current), and output power amount (power generation amount) on the display unit 36, the display unit 36 has a function of instructing which data to display.

  Here, the operation data writing process in the power conditioner 30 having such a configuration will be described. When the DC power generated by the solar cell 10 and collected in the connection box 20 is input to the power conditioner 30, the DC power is converted into AC power by the power conversion unit 31 and output to the distribution board 40. Is done. At this time, the measurement calculation unit 32 measures the input voltage and input current input to the power conversion unit 31 and the output voltage, output current, and output power output from the power conversion unit 31 every predetermined measurement time. Moreover, the measurement calculation part 32 produces | generates the operation data containing the input voltage, input current, output voltage, output current, output electric power, and electric power generation amount which totaled these measured values for every predetermined total period, and the acquisition date. . Next, the data write processing unit 33 writes the operation data obtained from the measurement calculation unit 32 in the first and second storage units 34 and 35. Thus, the writing process of the operation data to the first and second storage units 34 and 35 is completed. The display processing unit 37 reads one of the operation data stored in the first storage unit 34 or the second storage unit 35 in accordance with an input from the display switching unit 38, and displays the display unit. 36.

  According to the first embodiment, the first and second storage units 34 and 35 are provided, and the operation data in the power generation system including the power conditioner 30 is stored in each of them. Even if the operation data is not saved due to a failure of the unit, the operation data is saved in the other storage unit, and there is no loss of the operation data, compared to the case where the operation data is saved with one storage means. Thus, the reliability of data storage is extremely high.

Embodiment 2. FIG.
FIG. 2 is a block diagram schematically showing a schematic configuration of a photovoltaic power generation system including a power conditioner according to the present invention. The power conditioner 30 of this solar power generation system has a configuration in which the second storage unit 35 of FIG. That is, the second storage unit 35a is directly or indirectly connected to an information processing terminal such as a personal computer, and is detachable storage such as a compact flash (registered trademark) memory that can read information therein by the information processing terminal. The power conditioner 30 is configured by a medium, and further includes a mounting portion 39 such as a connector to which the second storage portion 35a can be mounted. The other components are the same as those in FIG. 1 of the first embodiment, and the description thereof is omitted. At this time, since the first storage unit 34 does not need to be attached to or detached from the power conditioner 30, it is a fixed connection type such as a flash memory that is solder-mounted on a circuit board that realizes the function shown in FIG. It may be configured with a memory or the like. Also in such a power conditioner 30, the operation data obtained by the measurement calculation unit 32 is written into both the first storage unit 34 and the second storage unit 35 by the data write processing unit 33.

  3A is a diagram illustrating an example of a front view of the power conditioner, and FIG. 3B is a diagram illustrating an example of a mounting state of the second storage unit in the power conditioner of FIG. 3A. is there. The power conditioner 30 includes a liquid crystal display 71 as a display unit 36, an operation key 72 as a display switching unit 38 for selecting contents displayed on the liquid crystal display 71, and a power conditioner on the front side of the main body 70. An LED (Light-Emitting Diode) 73 serving as a display unit 36 indicating the operation state of the na 30 and a door 74 provided in a space in which the second storage unit 35 is mounted are provided. The door 74 is pivotally supported by the main body 70 at the right end of the figure, and has a structure that can rotate around the axis of the right end. Inside the door 74, an attachment area 76 is provided as a space required when the Compact Flash (registered trademark) memory 75 is attached and detached as the second storage unit 35. A compact flash (registered trademark) card slot 77 as a mounting portion 39 for mounting a compact flash (registered trademark) memory 75 is provided on the left end side of the mounting area 76. With such a structure, the compact flash (registered trademark) memory 75 can be inserted into the compact flash (registered trademark) card slot 77 and removed if necessary.

  The removed compact flash (registered trademark) memory 75 is a personal computer connected to a personal computer having a compact flash (registered trademark) card slot or a card reader capable of reading the compact flash (registered trademark) memory 75. The contents of the compact flash (registered trademark) memory 75 are read by a computer or the like, and the operation data can be edited and tabulated.

  In the above description, the compact flash (registered trademark) memory 75 is described as an example of the second storage unit 35. However, the present invention is not limited to this, and an SD memory card or a compact flash (registered trademark) is used. Any storage medium that can be directly or indirectly connected to and detachable from a personal computer such as a card-type hard disk drive may be used.

  According to the second embodiment, one of the two storage units (second storage unit 35) is a removable storage medium such as a compact flash (registered trademark) memory. The operation data can be easily transferred to an information processing terminal such as a personal computer via the second storage unit 35. As a result, there is an effect that operation data can be aggregated and analyzed by the information processing terminal. Moreover, it has the effect that the 2nd memory | storage part 35 which preserve | saved the operating data of the solar power generation system installed in a certain place can be sent to another place by means, such as mail.

Embodiment 3 FIG.
In the first and second embodiments, the format of the operation data stored in the first and second storage units 34 and 35 is not defined. In the third embodiment, the format of operation data stored in the first and second storage units 34 and 35 will be described. Since the configuration of the power conditioner 30 in the third embodiment is basically the same as that in the first and second embodiments, the description thereof will be omitted, and only different parts will be described below.

  In the third embodiment, the first storage unit 34 stores binary operation data, and the second storage unit 35 stores CSV (Comma Separated Values) operation data. The Therefore, the data write processing unit 33 writes the operation data acquired from the measurement calculation unit 32 in the first storage unit 34 as it is in binary format data, and the second storage unit 35 stores binary format data. Is further provided with a function of performing conversion to CSV format and writing.

  With this configuration, since the operation data is stored in binary format in the first storage unit 34, for example, the numerical value “65535” becomes “1111 1111 1111 1111” in binary, Since it can be expressed, the capacity required for storage is 2 bytes. On the other hand, since the operation data is stored in the CSV format in the second storage unit 35, for example, the numerical value “65535” requires 1 byte per digit, so the capacity required for storage is 5 bytes. It becomes. That is, in the first storage unit 34, as a result of saving in the binary format, it is possible to store more operation data as compared with the second storage unit 35.

  Moreover, in the 2nd memory | storage part 35, as a file system which manages the data memorize | stored in the storage medium, it is the same format as the file system used with the information processing terminal which the administrator of a solar power generation system is using. It is desirable to use something. For example, if the file system of the information processing terminal of the administrator is FAT (File Allocation Tables), the second storage unit 35 is formatted with a FAT format file system, and the file system of the information processing terminal of the administrator is NTFS. If the file system of the information processing terminal of the administrator is HFS (Hierarchical File System), the second storage unit 35 is formatted with the NTFS file system. The second storage unit 35 is formatted such that the unit 35 is formatted with an HFS file system. Accordingly, if the operation data stored in the second storage unit 35 in the power conditioner 30 is, for example, in the FAT format, the storage medium constituting the second storage unit 35 is used as the file system in the FAT format of the administrator. By connecting to the information processing terminal having the information processing terminal, the data processing terminal can directly read the data in the storage medium constituting the second storage unit 35 and perform processing. In particular, as in the case of the second embodiment, if the second storage unit 35 is a detachable storage medium, the storage medium is directly attached to the information processing terminal or a storage medium reading device connected to the information processing terminal. Only by doing this, the operation data stored in the second storage unit 35 can be read and processed. Further, by storing the operation data in the CSV format, it is possible to aggregate the operation data using a commercially available spreadsheet software or to check the data content with a general editor.

  In the case of the first embodiment in which both the first and second storage units 34 and 35 cannot be attached and detached, CSV format operation data is stored in the first storage unit 34 and binary in the second storage unit 35. You may make it preserve | save the driving | operation data of a format. In the case of the first embodiment, the operation data in the CSV format is read from the first storage unit 34 or the second storage unit 35 via a communication means (not shown) for connecting to the information processing terminal. Shall.

  According to the third embodiment, the second storage unit 35 of the two storage units is formatted with the same file system as the information processing terminal of the administrator, and the CSV format operation data is stored there. When the second storage unit 35 is connected to the information processing terminal of the administrator, the saved operation data can be directly read. In particular, when the second storage unit 35 is configured by a removable storage medium, the second storage unit 35 can be removed and connected to the information processing terminal, and operation data management and information processing terminal can be performed. This has the effect of making it easier to move. Further, in the CSV format, it can be read by almost any application such as commercially available spreadsheet software or an editor, and it becomes possible to perform aggregation and analysis, which has an effect of high convenience. Furthermore, since the operation data is saved in the binary format in the other first storage unit 34, the data size is smaller than in the case of saving in the CSV format. Even if the units 34 and 35 have the same capacity, more data can be stored in the first storage unit 34.

Embodiment 4 FIG.
FIG. 3A shows an overview of the front surface of the power conditioner 30. The size of the display unit 36 such as the liquid crystal display 71 provided in the power conditioner 30 is as small as, for example, 128 dots × 64 dots. Many are not large enough to display a large amount of information. For example, when displaying the amount of power generation on the display unit 36 of 128 dots × 64 dots in a graph, if the scales of the vertical axis and the horizontal axis are entered, the graph itself becomes small, so the vertical axis and the horizontal axis There is no choice but to display without a scale. However, in this case, only the power generation trend can be read. Therefore, in the fourth embodiment, a data display processing method in the case where the power conditioner 30 of the first to third embodiments is provided with a display unit 36 having a size that cannot accommodate the coordinate axis scale will be described. To do.

  FIG. 4 is a diagram illustrating an example of the structure of display screen data managed by the display processing unit. The display processing unit 37 hierarchically manages a menu screen, a submenu screen, and a display screen to be displayed on the display unit 36. In the example of FIG. 4, the menu screen displays a “data” item for displaying data numerically and a graph or table of operation data that can be placed within a predetermined period of time. A "graph-table" item is provided. Below the “data” item, a submenu screen is provided for displaying each item such as generated power, total accumulated power generation, DC voltage, DC current, output voltage, and output voltage as operation data. A display screen for displaying numerical values corresponding to the respective items is provided below these items. On the other hand, a submenu screen having items such as “daily power generation”, “monthly power generation”, and “annual power generation” is provided below the “graph-table” item on the menu screen. A display screen for displaying a graph and a table corresponding to each item is provided below these items.

  5A to 5D are diagrams illustrating examples of screens displayed on the display unit by the display processing unit. These figures are based on the structure of the display screen data shown in FIG. FIG. 5A is a diagram illustrating an example of a menu screen. The menu screen 100 has two items “data” and “graph-table”, and a selection button 101 is displayed for each item. It is assumed that the item for which the selection button 101 is black indicates the currently selected item.

  In the fourth embodiment, as an example, the display switching unit 38 is configured by operation keys 72 pointing in four directions, up, down, left, and right, as shown in FIG. 3-1. These operation keys 72 are used when selecting items displayed on the display unit 36 or switching the screen. In this example, when selecting an item on the display screen, the operation key 72 in the vertical direction is used, and when the selected item is determined and the display screen is shifted to a lower display screen, the operation key 72 in the right direction is used. When moving to a display screen higher than the current display screen, the left operation key 72 is used. FIG. 5A shows a lower screen display button 102 indicating that there is a screen that can be further displayed below.

  FIG. 5-2 shows a submenu screen when data is selected in FIG. 5-1. That is, in FIG. 5A, when the “data” item button 101 is made black using the up / down direction operation key 72 and the right direction operation key 72 is pressed, the display processing unit 37 displays FIG. The sub menu screen 110 is displayed on the display unit 36. This submenu screen 110 includes items of generated power, total accumulated power generation, DC voltage, DC current, output voltage, and output voltage, and a selection button 101 is displayed for each item. However, since there are too many items in this submenu screen 110 to include all items, in the initial state, each item of output voltage and output current is displayed in the display area of the display unit 36 (solid line in the figure). (Area surrounded by) are not displayed. In order to display these items, if the operation key 72 in the downward direction is pressed so that the output voltage or output current selection button 101 becomes black, the contents of the display screen are scrolled and displayed. . The sub-menu screen 110 also displays a lower screen display button 102. When the left operation key 72 is pressed on the sub menu screen 110 in FIG. 5B, the display processing unit 37 detects this and displays the menu screen 100 in FIG. Do.

  FIG. 5C illustrates a display screen when the generated power is selected in FIG. That is, in FIG. 5B, when the “power generation” selection button 101 is made black using the up / down direction operation key 72 and the right direction operation key 72 is pressed, the display screen 120 in FIG. Move. The display processing unit 37 performs a process of extracting the current generated power from the first storage unit 34 or the second storage unit 35 and displaying it on the display screen 120. When the left operation key 72 is pressed on the display screen 120 in FIG. 5C, the display processing unit 37 detects this and displays the submenu screen 110 in FIG. Process. The same applies when another item is selected and displayed in FIG.

  FIG. 5-4 shows a submenu screen when the graph-table is selected in FIG. That is, in the menu screen 100 of FIG. 5A, when the “Graph-Table” selection button 101 is made black using the up / down operation keys 72 and the right operation key 72 is pressed, the display processing unit 37 performs processing so that the sub-menu screen 130 of FIG. The submenu screen 130 includes items for daily power generation, monthly power generation, and annual power generation, and a selection button 101 is displayed for each item. The sub-menu screen 130 also displays a lower screen display button 102. When the left operation key 72 is pressed on the submenu screen 130 in FIG. 5-4, the display processing unit 37 detects this and displays the menu screen 100 in FIG. Do.

  FIG. 5-5 shows a display screen when one-day power generation is selected in FIG. 5-4. That is, on the submenu screen 130 of FIG. 5-4, the “daily power generation” selection button 101 is made black using the up / down operation key 72 and the right operation key 72 is pressed. The processing unit 37 performs processing to display the display screen 140 of FIG. The display processing unit 37 extracts data indicating the power generation of one day (for example, operation data indicating the power generation amount per hour of the day) from the first storage unit 34 or the second storage unit 35 and graphs it. To display on the display screen. On this graph screen, a graph area 141 in which the power generation amount for one hour, for example, every day is displayed in a bar graph, the total integrated value 142 of the power generation amount for that day, and the like are displayed. As shown in this figure, in the graph of the graph area 141, the display area of the display unit 36 is small, so that the horizontal axis represents scale display such as 0 o'clock, 6 o'clock, 12 o'clock,. The scale display such as 0 kWh and 10 kWh cannot be displayed on the vertical axis. For this reason, the administrator cannot see how much power is generated at each time by looking at this screen. For example, even if the display unit 36 is large enough to display a scale display, only a rough power generation amount can be estimated from the graph.

  Therefore, the display processing unit 37 of the fourth embodiment provides the lower screen display button 102 on the graph display screen 140 and displays the table corresponding to the graph by pressing the right operation key 72. It has a function to make it. FIG. 5-6 shows a table display screen corresponding to the graph of FIG. 5-5. As shown in FIG. 5B, the table of the display screen 150 displays all the data corresponding to the graph of FIG. 5-5 at a time, and scrolls the portion that does not appear in the display area. However, all the data corresponding to the graph of FIG. 5-5 may be divided into the number of data that can be displayed on the screen of the display unit 36 and displayed. For example, in the case of the graph of FIG. 5-5, since the horizontal axis is the time of one day (24 hours), this is 0 to 5 o'clock, 6 o'clock to 11 o'clock, 12 o'clock to 17 o'clock, 18 o'clock to 23 o'clock. As shown in Table 1-1, Table 1-2, Table 1-3, and Table 1-4 divided into every 6 hours, each time the right operation key 72 is pressed, graph → Table 1- The contents to be displayed may be switched in the order of 1 → Table 1-2 → Table 1-3 → Table 1-4 → Graph →. In this case, when the left operation key 72 is pressed on each of the graph or table display screens 140 and 150, the display processing unit 37 detects this and displays the submenu screen 130 shown in FIG. 5-4. Processing to display on the display unit 36 is performed. In addition, when monthly power generation or annual power generation is selected in FIG. 5-4, the same processing is performed, and when the operation data is divided and displayed at the time of switching from the graph to the table, In the month, a table is created by dividing the first day to the 31st into four categories, for example, and in the year from January to December, a table is created, for example, divided into four categories. By displaying each time the button 72 is pressed, it is possible to provide a state in which the contents can be browsed without scrolling.

  Thus, by displaying the graph and the table continuously in the display processing unit 37, the administrator knows the transition of the power generation amount from the graph on the display screen 140 of FIG. 5-5, and FIG. The numerical information of the power generation amount at the time (day, month) can be obtained from the table of the display screen 150. As a result, it is possible to obtain necessary information from the display unit 36 of the power conditioner 30 without having a large screen display unit 36 like a personal computer.

  In addition, the content displayed on the display part 36 shown in FIG.4 and FIG.5-1-FIG.5-6 is an illustration, and can be arbitrarily determined by the administrator and user of a power generation system. For example, any date, month, and year can be selected and displayed.

  According to the fourth embodiment, when the graph of the operation data for a predetermined period cannot be displayed on the small display unit 36 provided in the power conditioner 30, the graph can be displayed following the graph. Since the display processing unit 37 that continuously displays the table corresponding to the above by the input through the display switching unit 38 from the user is provided, the administrator can confirm the operation data with the graph and the table. Has the effect of being able to. Specifically, a graph without a scale is used to check the transition of operation data, and the table that is displayed after this graph is used to check a specific numerical value of when and how much power is generated in the graph. Therefore, the state of the photovoltaic power generation system can be easily confirmed by using the transition of the power generation amount and the contents thereof without connecting to a personal computer and transferring the operation data. Thereby, even if the dot resolution of the display unit 36 is as small as about 128 dots × 64 dots, for example, the information requested by the administrator can be provided on the spot. Furthermore, it is not necessary to prepare a large display unit 36 for displaying information requested by the administrator in the power conditioner 30, and it is only necessary to provide a small display unit 36, and the manufacturing cost can be reduced. Have.

  As described above, the power conditioner according to the present invention converts the DC power from the power generation source into AC power and supplies the power to the load, or reversely flows to the commercial power source (system). Suitable for power generation systems such as

Claims (4)

Power conversion means for converting the DC power of the power generation source into AC power;
Measurement calculation means for calculating parameters related to power conversion by the power conversion means and calculating operation data;
A communication means for communicating with the information processing terminal;
First storage means for storing operation data calculated by the measurement calculation means in a first data format;
Second storage means for storing the operation data calculated by the measurement calculation means in a second data format that can be directly read by application software installed in the information processing terminal;
Data writing processing means for performing processing for writing the operation data in the first and second storage means;
With
The data writing means saves the operation data in the first data format in the first storage means, and converts the operation data in the first data format into the second data format. The power conditioner is stored in the second storage means, and the operation data is stored in duplicate in different data formats. Power conversion means for converting the DC power of the power generation source into AC power;
Measurement calculation means for calculating parameters related to power conversion by the power conversion means and calculating operation data;
First storage means for storing operation data calculated by the measurement calculation means in a first data format;
Removable second storage means for storing operation data calculated by the measurement calculation means in a second data format;
Data writing processing means for performing processing for writing the operation data in the first and second storage means;
With
The second data format is a data storage format in which the operation data can be directly read by an application installed in an information processing terminal to which the second storage means can be attached.
The data writing means saves the operation data in the first data format in the first storage means, and converts the operation data in the first data format into the second data format. The power conditioner is stored in the second storage means, and the operation data is stored in duplicate in different data formats.   The power conditioner according to claim 1 or 2, wherein the first data format is a binary format, and the second data format is a CSV format. Display means;
Display processing means for reading the operation data from the first or second storage means and displaying the operation data on the display means;
Display switching means for switching contents to be displayed on the display means;
Further comprising
The display processing means, when displaying operation data within a predetermined period, a graph display screen for displaying the operation data within the predetermined period without including a horizontal axis and a vertical scale, and the predetermined period 4. The display device according to claim 1, further comprising a function of switching a table display screen displaying the operation data in the table on the basis of an instruction from the display switching unit and displaying the table on the display unit. Power conditioner described in one.

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