KR20100082669A - Solar cell modul - Google Patents

Abstract

PURPOSE: A solar module monitoring system is provided to rapidly grasp the reason of a power productivity deterioration by monitoring each solar module. CONSTITUTION: A sensing unit(11) senses current or voltage generated from each solar module(10). A transmitter(12a) transmits data from the sensing unit through a transmitting and receiving medium. A receiver(16a) receives data transmitted from the transmitter. A server(18) constructs the database by collecting the data of each solar module. A display unit(19) displays the value collected in the database of the server.

Description

Solar Module Monitoring System {SOLAR CELL MODUL}

The present invention is to monitor the status of each solar module constituting the solar power plant individually to quickly determine whether the solar module defective or failure to take action to improve the efficiency in terms of maintenance of the facility to maximize the power productivity Solar module monitoring system.

As shown in FIG. 5, the solar modules in each solar group divided into a plurality of groups are connected in series to produce a DC current, and the inverter receives the generated DC current and converts it into AC and at a high voltage. It boosts and transmits power.

 The amount of transmission is metered and the owner of the power plant is profitable by the contract with the power exchange.

Factors affecting the generation amount can be divided into natural and technical factors. Natural factors are divided into the geographic factor where the array is installed and the most important climatic factor for the limited amount of light from the sun. This is a given resource that cannot be secured by manpower.

The technical factors are divided into performance factors of solar modules, light receiving behavior elements of solar modules, electrical connection patterns between solar modules, and maintenance elements of solar modules.

Since the performance factor of the solar module is determined by the speed of technological development in the art, it takes a lot of time and cost to overcome it, but the remaining elements are factors that can be overcome in the short term through the management of the installed devices.

Regarding the light reception behavior of solar modules, this method is already implemented because it is a sensor or control program technology that increases efficiency by actively receiving sunlight by tracking sunlight on one axis and two axes.

Since the electrical connection pattern between solar modules determines whether the solar modules are connected in series or in parallel according to the performance of the inverter, there is no longer a choice after design and construction.

In addition, the management of solar modules has been known so far in terms of measuring the amount of power collected at last for performance degradation or failure. In other words, the produced electricity is recorded by the inverter every day, the manager has to compare and review the record to determine whether there is an abnormality of the power generation system. Even if an abnormality in the power generation system is detected, finding the cause of the problem is time-consuming because it can only be relied on by primitive methods such as visual inspection of the administrator or individual performance test. This will incur a large amount of power loss in the time it takes to find the cause of the problem and take action. In particular, this problem increases as the solar module ages. That is, each solar module has inherent characteristics such as lifespan or structural weakness, and as time passes, the characteristics of the solar modules appear to be malfunctioning or deteriorating, which in turn negatively affects the overall power generation efficiency. For example, if a solar module deteriorates or malfunctions in a solar module connected in series, the overall power productivity is negatively affected even if the function of the other solar module is normal.

The company that manufactures solar modules admits that the product defect rate is around 0.1%. In some ways, 0.1% may be negligible, but the damage caused by the failure rate in a large power plant is considerable in years.

In other words, the electricity lost due to product failure or failure will accumulate over time, and if it accumulates in the long term for 15 or 20 years when the power generation difference is guaranteed, the damage will increase enormously and needs to be improved.

The present invention is to establish a monitoring system that individually manages the state of each solar module to quickly identify and predict the cause of lowering the power productivity, so that the power plant can maintain the best power condition at all times. The purpose is to maximize power productivity.

The present invention for achieving the above object,

Sensing unit for sensing the current or voltage generated in each solar module;

A transmitter for transmitting data from the sensor through a transmission / reception medium;

A receiving unit which receives the data transmitted from the transmitting unit;

A database unit for collecting and arranging data of each received solar module;

A display unit displaying the collected values of the database unit; Is achieved by configuration.

In addition, the data transmission and reception medium implemented in the present invention is achieved by using power communication.

In addition, the database unit is further provided with a comparison unit for comparing the data of each solar module collected to find a problem value, it is achieved by displaying the values of the problem filtered by the comparison value.

The present invention can monitor the status of each solar module individually, so that it is possible to quickly determine the cause of the decrease in power productivity, and to check the degradation state of performance in real time, thereby predicting the lifespan thereof, and thus to cope with it quickly. The power plant has the advantage of maintaining the best power condition at all times.

In addition, the monitoring of solar modules minimizes and saves the electric energy that is invisible due to various causes, and as a result, if the cumulative calculation of the power generation gap is accumulated for 15 years and 20 years, the enormous income is returned to the owner of the power plant. And furthermore, it has the effect of remaining a great profit nationally.

1 is a block diagram of a solar module monitoring system constituting a power plant according to a first embodiment of the present invention.

As shown in the figure, in each solar module 10, a sensing unit 11 measuring voltage or current is configured in a transmission line for transmitting generated electricity.

Although the sensing unit 11 may use external power, it is preferable to use its own power generated by the solar module 10.

In addition, the transmitter 12a receives the data sensed by the sensing unit 11 and transmits the data. Correspondingly, the receiver 12b that receives the signal transmitted from the server 18 to be described later may be configured. At this time, each transmitting and receiving unit 12b is given an ID individually assigned.

The transmitter 12a may use a general wired communication line 14 or wireless communication, and may transmit and receive data through the power line 24 as shown in FIG. 2.

In order to transmit and receive data using the power line 24, an apparatus for loading data onto the power line 24 is required. When using the power line 24 it is not necessary to build a separate communication line for a separate data communication it is possible to reduce construction costs and material costs.

On the other hand, the data transmitted by the general wired communication line 14 or wireless communication is received through the receiver 16a. In particular, the data transmitted through the power line 24 is received through the receiving unit 16a before passing through an inverter that converts DC current into AC and transmits the data, and the data received by the receiving unit 16a is transmitted to the server 18. The data is collected and organized by the server 18 according to each ID. In addition, the transmitter 16b may be configured to transmit data from the server 18 to each solar module 10 in correspondence with the receiver 16a.

The information thus summarized determines an average value through a comparison unit, and compares each data value based on the average value to classify values having a tolerance or less.

The classified values are displayed to the manager through the display unit 19.

The driving time of the sensing unit 11 for collecting the abnormality of each solar module 10 may be selected and performed at specific time intervals, or may be made when the amount of sunshine is good and the overall power production conditions are good.

Since the failure progressed by the aging of the solar module 10 is made slowly, it may be sufficient to set an appropriate time interval of sensing or more about once or twice a day.

The transmission of data may be actively sent according to a set time or power generation conditions, but may be manually sent when the server 18 receives a command for requesting data.

1 is a block diagram of a solar module monitoring system according to the present invention.

2 is a block diagram of a solar module monitoring system using power communication in accordance with the present invention.

*** Explanation of symbols for main parts of drawing ***

10-solar module 11-sensing unit

12-transceiver 14-wired communication line

16-Receiver 18-Server

19-display unit 24-power line

Claims (4)

A sensing unit 11 for sensing current or voltage generated by each solar module 10; A transmitter 12a for transmitting data from the sensor 11 through a transmission and reception medium; A receiving unit 16a for receiving data transmitted from the transmitting unit 12a; A server 18 which collects data of each received solar module and builds a database; A display unit 19 for displaying the collected values in the database of the server 18; Solar module monitoring system, characterized in that consisting of. The solar module monitoring system according to claim 1, wherein the data transmission / reception medium communicates using a power line (24). The method of claim 1 or claim 2, wherein the server 18 has a comparison unit for finding a problem value by comparing the data of each solar module 10 collected in the database, the problem of the problem filtered by the comparison value Solar module monitoring system characterized in that to display the values via the display unit (19). 3. The apparatus of claim 1 or 2, further comprising: a transmitter (16b) for transmitting a command signal for data sensing in said server (18); The solar module monitoring system, characterized in that it further comprises a receiver for receiving a command signal from the server (18) in the solar module (10) through the transmitter (16b).

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