JPH0956181A - Solar power generating equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make the maintenance and inspection of a solar cell panel having a lowered power generating efficiency by identifying and indicating a solar cell unit after a solar cell unit not reaching a predetermined level was judged to be a solar cell unit requiring maintenance and inspection. SOLUTION: A solar cell panel (SP) 1 is divided by a unit. A multiple cable 3 contains m×n output, detection line 3b for detecting the output for each unit, of SP1. A microcomputer 11 calculates a correction factor to be used when determining a predetermined level value for judging whether the power generating efficiency of SP1 divided for each unit has been lowered. And the predetermined level value is compared to the generated power output of SP1 for each unit, solar cell panels for each unit where the generating efficiency has been lowered are accurately identified, and identification indicating for the SP1 of the unit address number for each unit, where the generating efficiency has dropped, is shown on a CRT display 14.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photovoltaic power generator, and more particularly to a photovoltaic power generator that facilitates maintenance and inspection.

[0002]

2. Description of the Related Art In a conventional solar power generation device, for example, a solar cell panel composed of a plurality of solar cell units arranged two-dimensionally on a roof of a house is arranged at an angle capable of receiving a solar ray. The generated power remains DC,
Alternatively, it is converted to AC power and supplied to the load for use.
When the solar panel is placed on the roof, etc., the direction and angle of the sun change depending on the seasons and the time of day, so the solar panel can be changed to the south when the fixed type is used. Some objects are automatically controlled to face the sun.

[0003]

Since the conventional photovoltaic power generation device is configured in this way, the output is reduced and the power generation efficiency is reduced due to the failure of the solar cell unit constituting the solar cell panel. In this case, maintenance and inspection will be performed on the entire solar cell panel, and especially when the roof is grounded, maintenance and inspection is not easy and there is a problem that maintenance and inspection takes time.

The present invention has been made to solve the above problems, and an object of the present invention is to reduce the output of a solar cell unit due to deterioration of a part of the solar cell unit and to reduce the power generation efficiency. It is to provide a solar power generation device that facilitates maintenance and inspection of panels.

[0005]

A solar power generation device according to the present invention is a solar power generation device for supplying electric power generated by a solar cell panel composed of a plurality of solar cell units to a load. Unit output detection means that can detect the output level for each, and the power output of each solar cell unit by the unit output detection means is compared with a predetermined level value, the solar cell unit that has not reached the predetermined level value for maintenance inspection It is characterized by comprising an efficiency determining means for determining that the solar cell unit is a necessary solar cell unit, and a display means for distinguishably displaying the solar cell unit determined to require maintenance and inspection by the efficiency determining means.

Further, the unit output detecting means of the solar power generation device according to the present invention is characterized by including a switching circuit for switching the output detecting line connected to each unit by a control signal.

Further, the predetermined level value of the photovoltaic power generator according to the present invention is a level coefficient corresponding to the level value corresponding to the earth latitude of the installation area, and a level corresponding to the sun position based on the season day of the earth revolution. Revolution coefficient to be corrected to the value, rotation coefficient to be corrected to the level value corresponding to the sun position based on the time of day of the earth's rotation, and installation angle coefficient to be corrected according to the installation angle between the solar panel surface and the ground It is characterized in that the angle between the solar cell panel surface and the sunlight at the time of detecting the level value is calculated and determined based on the four coefficients of and.

Further, the latitude coefficient of the photovoltaic power generator according to the present invention is calculated by obtaining the latitude based on the earth information input from the input device, and the revolution coefficient and the rotation coefficient are the sun position based on the calendar clock. The solar cell panel mounting angle is calculated based on an angle detection unit.

According to the present invention, a plurality of solar cell units are output in a predetermined order, for example, in a unit address number order, by a switching circuit that switches a detection line connected to each of the plurality of solar cell panels according to a control signal. Detect and
The power generation output of each solar cell unit is compared with a predetermined level value, and the solar cell unit that has not reached the predetermined level value is determined to be a solar cell unit that needs maintenance and a solar cell that needs maintenance and inspection. By displaying the unit so that it can be identified, for example, by the unit address number,
This makes it easy to identify the solar cell unit with reduced power generation efficiency and reduces the burden of performing maintenance and inspection work on the solar cell panel.

Further, the output of the solar cell panel is detected for each of a plurality of solar cell units, and the power generation output for each of the solar cell units is calculated from the latitude coefficient obtained based on the input regional information and the calendar timer. Revolution coefficient according to the position of the sun obtained based on the obtained current date, rotation coefficient according to the sun position obtained based on the time of day, and according to the mounting angle of the solar cell panel It is determined that the solar cell unit that does not reach the predetermined level value is a solar cell unit that requires maintenance and that the maintenance and inspection is required. By distinguishably displaying the solar cell unit, the solar cell unit whose power generation efficiency is decreasing can be identified more accurately and easily, and maintenance work of the solar cell panel can be performed. To reduce the burden.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is an arrangement configuration diagram showing a state in which the solar power generation device of the present embodiment is attached. In the figure, 1 is a solar cell panel, which is divided into units. Reference numeral 2 is a roof to which the solar cell panel 1 is attached, 3 is a multi-core cable that connects the solar cell panel 1 and the control unit 4, and a DC power line 3a for extracting DC power generated in the solar cell panel 1 It is composed of m × n output detection lines 3b for detecting the output of each unit of the solar cell panel. An angle detection unit 5 includes an angle detection sensor that detects a mounting angle of the solar cell panel.

FIG. 2 is a unit diagram showing the configuration of the solar cell panel 1 and the control unit 4, and in the figure, 1a shows one unit of m × n solar cell panel 1. 3b
Is an output detection line for detecting the output of each unit of the solar cell panel 1, and the number of output detection lines (m × n) according to the number of units is provided. Reference numeral 11 is a microcomputer of the control unit 4. Reference numeral 11a denotes a memory, in which a table TB storing latitude coefficient information (L1, L2 ... LN) which is a coefficient according to the latitude for each region (E1, E2 ... EN) shown in FIG. A correction coefficient calculation program CP for calculating a correction coefficient used when obtaining a predetermined level value for determining whether or not the power generation efficiency of the solar cell panel divided for each unit is lowered is set. . The correction coefficient calculation program CP includes a latitude coefficient calculation program for obtaining a latitude coefficient which is a correction value according to the latitude coefficient information, and a program for supplementing it since the correct efficiency cannot be known only by the latitude coefficient. ing. First, the season, that is, the change due to the Earth's revolution, is a revolution coefficient calculation program for obtaining the revolution coefficient that is a correction value according to the altitude direction of the sun from each month and day. A rotation coefficient calculation program for obtaining a correction value, that is, a rotation coefficient that is a correction value according to the altitude and direction of the sun at each time due to the rotation of the earth,
It is a panel angle correction coefficient calculation program for obtaining a panel angle correction coefficient corresponding to the mounting direction and angle of the solar cell panel. Reference numeral 12 is a switching circuit for switching the m × n output detection lines 3b by a control signal of the microcomputer 11, 13 is an A / D converter, 14 is a CRT display, 15 key input section, and 16 is a clock with calendar.

Next, the operation of this embodiment will be described. In this solar power generation device, direct-current power of a predetermined voltage generated by some units of the solar cell panel is supplied to the load as it is or as direct-current power. If some of the solar cell panel units deteriorate and their power generation efficiency decreases, it becomes impossible to supply sufficient electric power to the load, and therefore it is necessary to regularly perform maintenance and inspection of the solar cell panel. Although it is important to identify the solar cell unit whose power generation efficiency is decreasing in this maintenance inspection, the solar cell panel is composed of multiple units, and the solar cell whose power generation efficiency is decreasing Identifying units is not easy. Therefore, as will be described with reference to FIG. 2, unit output detection means capable of detecting the output level is provided for each of the plurality of units of the solar cell panel, and it is inspected whether the power generation output for each unit is equal to or higher than a predetermined level value.

The predetermined level value used in this case is the latitude of the area where the solar cell panel subject to maintenance and inspection is installed, the month and day of the year, the time of day, and the solar cell panel. It is necessary to use a predetermined level value according to the installed direction and elevation. This depends on the latitude of the area where the solar panels subject to these maintenance inspections are installed, the month and day of the year, the time of day, and the direction and elevation of the solar panel installation. This is because the power generation output of the solar cell panel is different.

The procedure for determining the predetermined level value will be described below. The electromotive force, that is, the power generation output of the solar cell panel is determined by the product of the light amount S applied to the solar cell panel, the area D of the solar cell panel, and the power generation efficiency k of the solar cell panel. However, the power generation output thus obtained is the case where the surface of the solar cell panel is installed perpendicular to the sun rays. On the earth, the angle of the sun's rays with respect to the surface of the solar cell panel varies depending on the latitude of each region even at the same time. Therefore, it is necessary to correct the power generation output of the solar cell panel by the latitude coefficient according to the latitude of the area. Therefore, enter the area information where the solar cell panel is installed from the key input unit 15,
Latitude coefficient information is obtained from the table TB shown in FIG. 3, and a latitude coefficient L corresponding to the area is obtained from the latitude coefficient information program, which is multiplied by the power generation output to perform correction.
The predetermined level value is defined as the light amount S × the area D of the solar cell panel ×
It is determined by the power generation efficiency k × latitude coefficient L.

However, since the earth revolves around the sun, the angle of the sun's rays with respect to the surface of the solar cell panel also differs depending on the date of the year, so it is necessary to correct the revolution. The revolution coefficient for this purpose is calculated by a revolution coefficient calculation program. The calculation of the revolution coefficient by this revolution coefficient calculation program obtains information about the current date based on the output of the calendar clock 16 and knows the direction and elevation of the sun based on this date. The revolution coefficient R is calculated from the elevation angle. Then, the predetermined level value is obtained and determined by the light amount S × area of the solar cell panel D × power generation efficiency k × latitude coefficient L × revolution coefficient R.

Further, since the earth is rotating, the angle of the sun's rays with respect to the surface of the solar cell panel also varies depending on the time of day, so it is necessary to correct the rotation. The rotation coefficient for this purpose is calculated by the rotation coefficient calculation program. The calculation of the rotation coefficient by this rotation coefficient calculation program obtains information about the current time based on the output of the calendar clock 16 and knows the direction and elevation of the sun based on this time. The rotation coefficient Ro is calculated by a rotation coefficient calculation program. Then, the predetermined level value is obtained and determined by the light amount S × area of the solar cell panel D × power generation efficiency k × latitude coefficient L × revolution coefficient R × rotation coefficient Ro.

Furthermore, since the solar cell panel is usually installed at an angle depending on the ground or the roof of the building, the panel angle correction coefficient θo corresponding to the mounting angle detected by the angle detection unit 5 is corrected. The predetermined level value is obtained by a coefficient calculation program, and the predetermined level value is calculated as: light amount S × area of solar cell panel D × power generation efficiency k × latitude coefficient L × revolution coefficient R × rotation coefficient Ro × panel angle correction coefficient θ
It asks and decides by o. Here, the product of four coefficients θ (L × R ×
Ro × θo) corresponds to a panel angle correction coefficient which is the angle between the sunlight and the solar cell panel surface at the detection time. The above calculation processing of the predetermined level value is collectively shown in FIG. 5 as a flowchart of steps S51 to S55.

By comparing the predetermined level value thus obtained with the power generation output of the solar cell panel of each unit, the solar cell panel of each unit whose power generation efficiency is decreasing is accurately identified to determine the power generation efficiency. The identification display for the solar cell panel of the unit address number for each unit whose power consumption is decreasing is displayed on the CRT display 14. FIG. 4 shows an example of the display. In this example, the unit address numbers (3, 2) and (m, 4) in the panel of the solar cell are below a predetermined value, and the state determined to be defective is displayed.

Therefore, according to the present embodiment, it is possible to accurately grasp the solar cell panel having the unit address number whose power generation efficiency is lowered, which facilitates maintenance and inspection.
Further, as a result of abnormal display of the solar cell panel of the unit number displayed on the CRT display 14, it is possible to easily specify the unit of the solar cell panel to be subject to maintenance and inspection.

[0021]

As described above, according to the present invention, the deterioration of the power generation efficiency occurring in the solar cell panel for each unit can be accurately determined, so that the maintenance and inspection of the solar cell panel can be facilitated. is there.

[Brief description of drawings]

FIG. 1 is an arrangement configuration diagram showing a state in which a photovoltaic power generator according to an embodiment of the present invention is attached.

FIG. 2 is a unit diagram showing a configuration of a photovoltaic power generator according to an embodiment of the present invention.

FIG. 3 is an explanatory diagram showing a table TB that stores latitude coefficient information that is a coefficient according to latitude for each region of the photovoltaic power generator according to the embodiment of the present invention.

FIG. 4 is a display example of a defect determination unit in the photovoltaic power generator according to the embodiment of the present invention.

FIG. 5 is a flowchart of a calculation process of a predetermined level value according to the present invention.

[Explanation of symbols]

 1 Solar Cell Panel 1a Unit 4 Control Unit 11 Microcomputer (Efficiency Judgment Means) 14 CRT Display (Display Means) 16 Clock with Calendar

Claims (4)

[Claims] 1. In a solar power generation device for supplying a load with electric power generated by a solar cell panel including a plurality of solar cell units, unit output detection means capable of detecting an output level for each unit of the solar cell panel, Efficiency determination means for comparing the power generation output of each solar cell unit by a unit output detection means with a predetermined level value and determining that the solar cell unit that has not reached the predetermined level value is a solar cell unit requiring maintenance and inspection. A photovoltaic power generation device, comprising: a display unit that identifiably displays the solar cell unit determined to require maintenance and inspection by the efficiency determination unit. 2. The solar power generation device according to claim 1, wherein the unit output detection means includes a switching circuit that switches an output detection line connected to each unit according to a control signal. 3. The predetermined level value is a latitude coefficient that is corrected to a level value that corresponds to the earth latitude of the installation area, and a revolution coefficient that is corrected to a level value that corresponds to the sun position based on the seasonal day of the earth revolution. Level based on four coefficients: a rotation coefficient that corrects to the level value that corresponds to the sun position based on the time of day on the earth's rotation, and a mounting angle coefficient that corrects to the mounting angle between the solar cell panel surface and the ground The solar power generation device according to claim 1 or 2, wherein an angle between the solar cell panel surface and sunlight at the time of value detection is calculated and determined. 4. The latitude coefficient is calculated by calculating the latitude based on the earth information input from an input device, and the revolution coefficient and the rotation coefficient are calculated by calculating the sun position based on a calendar clock.
The solar power generation device according to claim 1, 2, or 3, wherein the solar cell panel mounting angle is calculated based on an angle detection unit.