KR101868350B1 - Photovoltaic power generating apparatus and operation method of the same - Google Patents

Abstract

A photovoltaic power generation apparatus and a method of operating the same are disclosed. A solar cell power generation apparatus and a method of operating the same according to an embodiment of the present invention can operate in a plurality of parallel connected inverters based on the amount of generated power output from the solar cell module, It is possible to generate electric power even when a fault occurs in the electric power supply system. In addition, by setting a plurality of inverters connected in parallel to the master inverter or the slave inverter according to the cumulative power amount, unnecessary driving of the inverter is limited, thereby extending the lifetime of the inverter.

Description

[0001] PHOTOVOLTAIC POWER GENERATING APPARATUS AND OPERATION METHOD OF THE SAME [0002]

The present invention relates to a photovoltaic power generation apparatus and a method of operating the same, and more particularly, to a photovoltaic power generation apparatus capable of independently controlling a plurality of inverters in parallel according to the amount of power generated from the photovoltaic module and a method of operating the same.

Generally, a photovoltaic power generation apparatus forms an array by connecting one or more solar cell modules in series or parallel to convert solar energy into electric energy, and applies direct current (DC) power generated in the solar cell array to a load or transmission line network And has an inverter for converting to alternating current (AC) power.

In this way, when a plurality of solar cell modules are connected in series or in parallel, for example, when the solar cell module shadows due to a surrounding environment such as a cloud passing or a nearby object, The point at which maximum power generation can be performed depends on the voltage and current of the power source. In addition, development points may vary depending on the types of solar cell modules, such as crystalline solar cells, amorphous solar cells, and fuel-responsive solar cells. Further, even the same type of solar cell module may have different points of development due to manufacturing errors during production. In particular, when the solar cell modules are connected in series, the solar cell module with the lowest current determines the total current value, and when the solar cell modules are connected in parallel, the lowest voltage determines the total voltage. Even if a plurality of solar cell modules have different power generation points due to these phenomena, the power generation point is determined by one solar cell module, so that the efficiency of the entire solar cell power generation device may be lowered. Accordingly, if the voltage of the solar cell module falls below the operating voltage for operating the inverter, the inverter may be turned off, resulting in loss of the generated power, and in some cases, the inverter may cause a loss of the entire generated power due to the failure .

On the other hand, in a general photovoltaic device, when electric energy is generated from a solar cell module composed of an array, the generated power source, that is, DC power, is first rectified by the rectifying part. That is, the generated DC power is DC power having a predetermined voltage from which pulsation components are removed by the filter provided in the rectifying unit. The DC power is then converted to AC power through the inverter section and supplied to the load. At this time, if the DC power flowing into the inverter section is lower than the rated voltage or if the voltage is irregular and is not suitable for the inverter operating condition, the inverter function is stopped. When the inverter function is stopped in this way, the connection between the inverter and the load is cut off, and the load is normally supplied with power from the commercial power supply.

Generally, the inverter has characteristics that the power conversion efficiency is greatly reduced while the output is low. Therefore, a method for efficiently driving the inverter even when the DC power output from the solar cell module is low should be sought. Also, in the case of driving a plurality of inverters connected to each other, only a specific inverter can be frequently operated. Accordingly, a method of efficiently driving the inverter while preventing the shortening of the life of the inverter at the same time, even when the amount of DC power generated from the solar cell module is low, should be considered.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to solve the above problems by providing a solar power generation apparatus capable of increasing the capacity of a solar power generation device by separately connecting and driving the plurality of parallel- And a method of operating the same.

It is still another object of the present invention to provide a method of setting one master inverter and a slave inverter on the basis of accumulated electric power amounts of a plurality of parallel connected inverters, And the life of the inverter can be extended by driving the inverter, and a method of operating the same.

A photovoltaic device according to an embodiment of the present invention includes at least one solar cell module; A plurality of inverters for converting DC power of the solar cell module into AC power and supplying the AC power to a load; A plurality of switches connecting the solar cell module to the inverter through a switching operation according to a control signal; And a control unit for driving the inverter and generating the control signal based on a DC power amount of the solar cell module, wherein the plurality of inverters are connected in parallel with each other, and the control unit controls the amount of DC power output from the solar cell module And a part or all of the plurality of inverters are driven in parallel based on the control signal.

In an embodiment, the control unit compares each cumulative power amount of the plurality of inverters, and sets the master inverter and the slave inverter according to the comparison result.

In an embodiment, the plurality of switches are located between an output terminal of the solar cell module and an input terminal of the plurality of inverters, and each of the switches connects or disconnects the solar cell module and the inverter.

In the embodiment, the control unit sets the master inverter to the smallest cumulative power amount among the plurality of inverters as a result of the comparison, and sets the remaining one as the slave inverter.

In an embodiment, the slave inverters are set in ascending order from slave inverters having a small cumulative power amount.

In an embodiment, the control unit may operate part or all of the master inverter and the slave inverter in parallel when the amount of DC power output from the solar cell module exceeds a predetermined allowable capacity of the master inverter.

In an embodiment, the plurality of inverters each include a control module connected through one or more communication lines, and the control modules communicate with each other using an RS-485 communication protocol standard.

The control unit may include a control module corresponding to each of the master inverter and the slave inverter and generates the control signal and the drive command of the plurality of inverters through a control module corresponding to the master inverter, do.

A method of operating a photovoltaic power generation apparatus according to an embodiment of the present invention includes: comparing cumulative power quantities of a plurality of inverters connected in parallel; Setting a master inverter and a slave inverter according to the comparison result; Determining whether the master inverter and the slave inverter are operated in parallel based on the amount of DC power output from the solar cell module; Converting the DC power of the solar cell module to AC power by driving the selected inverter according to the determination; And supplying the AC power to the load.

In the embodiment, the setting step is a step of setting the smallest accumulated power amount among the plurality of inverters to the master inverter and setting the remaining to the slave inverter.

In the embodiment, the step of determining whether or not to operate in parallel determines whether or not the parallel operation of the master inverter and the slave inverter is performed through a switching operation of a switch provided between an output terminal of the solar cell module and an input terminal of the plurality of inverters .

In an embodiment, the method further comprises resetting the predetermined master inverter and the slave inverter according to the amount of DC power and the driving time of the master inverter.

In the embodiment, the supplying step may include monitoring the load in real time, separating the inverter from the load when the load is determined to be abnormal according to a predetermined criterion, and controlling the load to be in a normal state And connecting the inverter to the load if it is determined.

In an embodiment, the plurality of inverters includes a control module connected to each other through one or more communication lines, and the control module communicates with each other using an RS-485 communication protocol standard.

The solar power generation apparatus and the method of operating the same according to the present invention can realize a large capacity of the solar power generation apparatus by connecting and operating a plurality of inverters connected in parallel based on the amount of generated power output from the solar cell module, It is possible to generate power even when a failure occurs in any of the inverters, so that the supply efficiency of the generated power can be increased.

The solar inverter and the slave inverter may be driven by setting the plurality of inverters connected in parallel to the master inverter or the slave inverter according to the cumulative power amount and driving the master inverter and the slave inverter according to predetermined conditions. It is possible to limit the unnecessary drive of the inverter and thus to prolong the life of the inverter.

Also, the solar power generation apparatus and the method of operating the same according to the present invention can individually drive a plurality of inverters connected in parallel through a master inverter, and even when the amount of DC output is increased by additionally providing a solar cell module, It is sufficient to additionally connect the inverters of the existing capacity as many as necessary without separately installing the inverters having a large capacity, so that the installation cost of the inverters can be reduced.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a photovoltaic device according to the present invention; FIG.
FIG. 2 is a diagram illustrating a parallel operation of a plurality of inverters in a schematic configuration of a solar cell generator according to the present invention; FIG.
3 is a flowchart illustrating an exemplary operation method of the photovoltaic device according to the present invention;

Hereinafter, a photovoltaic apparatus according to an embodiment of the present invention and a method of operating the same will be described in detail with reference to the accompanying drawings.

First, referring to FIG. 1, FIG. 1 shows a schematic configuration of a photovoltaic device according to the present invention. As shown in the figure, the photovoltaic device includes at least one solar cell module 100, a plurality of inverters 300, a plurality of switches 200 located between the solar cell modules and the inverter, a load 400, And a control unit 350.

The photovoltaic device converts DC power generated by using the solar cell module 100 into AC power through a plurality of parallel-connected inverters 300. The output AC power is supplied to the load 400. In the embodiment according to the present invention, the inverter 300 having the output power of 3.0 Kw will be described as an example.

In the solar cell module 100, one or more solar cell modules 100 are connected to each other in series or in parallel to form an array. Although FIG. 1 shows two solar cell modules 100, this is for the purpose of illustration. Generally, any number of solar cell modules 100 may be connected in series or in parallel. The solar cell module 100 absorbs sunlight to generate DC power (DC power). Further, the solar cell module 100 provides the generated DC power to the inverter 300 in order to convert it into electric power suitable for the load.

The inverter (300) converts DC power supplied from the solar cell module (100) into AC power. More specifically, the inverter 300 includes a filter and an inverter circuit, and the input DC power is supplied to an inverter circuit (not shown) through a noise filter (not shown). In addition, the inverter 300 supplies the AC power to the load 400. The inverter 300 may have a structure in which a plurality of inverters 300 are connected to each other.

In addition, the inverter 300 includes a plurality of switching elements (not shown) for inter-bus, and converts the DC power into AC power according to a control signal to apply the AC power to the load. The switching elements for the inverter may be, for example, an inverter circuit structure in which a pair of upper and lower arm switching elements connected in series to each other is formed and three pairs of upper and lower arm switching elements are connected in parallel. In addition, the inverter 300 may include a control module for driving the switching device for each inverter.

In an embodiment, the plurality of inverters 300 may include control modules 350a and 350b, respectively, which are connected via one or more communication lines. In this case, the control modules 350a and 350b may be provided inside the inverter 300 or may be provided outside the inverter 300. In this way, when the plurality of inverters 300 includes the control modules 350a and 350b, the control modules 350a and 350b can communicate with each other using, for example, the RS-485 communication protocol standard have.

More specifically, the control modules 350a, 350b may be coupled to each inverter 300 via one or more communication lines and may be interconnected with other control modules (not shown) via, for example, Communication can be performed. The interconnected control modules may exchange information such as information about the corresponding inverter 300, for example, the accumulated power of the inverter 300, whether it is a master inverter or not. In addition, the control modules 350a and 350b can respectively drive the corresponding inverters. Further, in the embodiment according to the present invention, a control command for driving a plurality of inverters is generated in the control module 350a of the master inverter and is transmitted to the other control module 350b connected thereto, as described below .

The switch 200 switches the switching element based on the control signal. The switch 200 connects the solar cell module 100 to the inverter 300 through a switching operation according to the control signal. The plurality of switches 200 may be disposed between an output terminal of the solar cell module 100 and an input terminal of the plurality of inverters 300, And the inverter.

More specifically, the switch 200 switches the switching device to connect the drive-determined inverter to the solar cell module according to the amount of DC power output from the solar cell module 100 and the accumulated amount of power of the inverter 300 do. The drive determination of the inverter is performed through the control unit 350 as described below. The switch 200 performs a switching operation for parallel operation of the inverter 300 according to a control signal transmitted from the control unit 350 do. In another embodiment, the control signal may be implemented by being generated and communicated by the control module 350a of the inverter set to the master inverter. That is, when the plurality of inverters 300 includes the respective control modules 350a and 350b, the switching operation of the switch 200 is performed based on the control signals transmitted from the respective control modules 350a and 350b . That is, the control modules 350a and 350b include inverters for exchanging accumulated power amount information of each inverter and setting information of the master inverter and / or the slave inverter using, for example, the RS-485 communication protocol standard And transmit a control signal to the switch 300, which commands the switching operation accordingly. On the other hand, when the master inverter among the plurality of inverters 300 is set, the switching operation of the switch 200 can be performed based on the control signal transmitted from the corresponding control module 350a.

In an embodiment, the plurality of switches 200 are connected in parallel with each other, and each of the switching elements may be alternately switched. For example, a plurality of switches 200 may be turned on alternately with different operating times, or may be turned on with some overlapping periods. For example, in FIG. 1, all of the switches 200 are in the turned-off state and the switches 200 are both in the turned-on state in FIG. 2, so that the turn-on operation times of the plurality of switches 200 can be driven differently . According to this, the operation of the inverter 300 for converting DC power into AC power can be alternately performed, so that it is possible to prevent the life span of the inverter 300 as a whole.

The control unit 350 generates a control signal for controlling the switching operation of the switch 200 based on the amount of DC power output from the solar cell module 100. In addition, the controller 350 determines whether to drive a part or all of the plurality of inverters 300 in parallel based on the amount of DC power output from the solar cell module. For example, as shown in the figure, when two inverters 300 each having an output power of 3.0 Kw are connected in parallel and the DC power generated from the solar cell module 100 is within 3.0 Kw, only one inverter is driven Since AC power conversion can be performed, it is determined that only the master inverter is operated alone. Accordingly, the control unit 350 transmits a control signal to the switch 200 so that only the master inverter is driven. On the other hand, when the generated DC power exceeds 3.0 Kw, which is the maximum permissible range of the individual inverter, it is determined that AC power conversion is performed by operating one master inverter and slave inverters of excess DC power in parallel. Accordingly, the control unit 350 transmits to the switch 200 a control signal for driving the master inverter and the slave inverter-the number of inverters to be driven and the driving order thereof, in parallel, depending on the DC power amount and the cumulative power amount of the inverter . When the generated DC power is much smaller than 3.0 Kw, it is determined that AC power conversion is performed by connecting a plurality of solar modules connected in parallel or series to one master inverter. Accordingly, the control unit 350 transmits a control signal to the switch 200 to connect the plurality of solar cell modules 100 to one master inverter.

The life of the inverter is greatly influenced by the drive time of the inverter. Here, the master inverter can be set according to a predetermined condition as described below, and can be replaced with other parallel-connected inverters, thereby preventing shortening of the life of the inverters.

In an embodiment, the control unit 350 compares each accumulated amount of power of the plurality of inverters 300. [ The controller 350 sets the master inverter and the slave inverter according to the comparison result of the accumulated power amount. Specifically, the control unit 350 sets the master inverter to the smallest cumulative power amount among the plurality of inverters, and sets the remaining inverters to the slave inverters. In particular, if the number of the slave inverters is plural, it is possible to select the slave inverters in ascending order from the slave inverters having a small cumulative power amount. That is, when a large amount of DC power is generated from the solar cell module 100, the controller 350 selects the slave inverters to be driven in parallel with the master inverter in the order of the smallest cumulative power amount and outputs a corresponding control signal to the switch 200 . In another embodiment, a comparison of the cumulative power amount of each inverter may be made via the control modules 350a, 350b provided for each inverter. That is, each of the control modules 350a and 350b connected to the inverter exchanges the accumulated power amount information of the inverters, sets the inverter having the smallest accumulated power amount as the master inverter, To share information. To this end, the control modules may communicate with each other using the RS-485 communication protocol standard. The control unit 350 may include control modules 350a and 350b corresponding to the master inverter and the slave inverter and may be connected to the switch 200 through the control module 350a corresponding to the master inverter. Or generate drive commands for other inverters.

In an embodiment, when the amount of DC power output from the solar cell module 100 exceeds a predetermined allowable capacity of the master inverter, the control unit 350 determines that some or all of the slave inverters are operated in parallel with the master inverter . For example, when the maximum output power of the individual inverter is 3.0 Kw and the DC power generated from the solar cell module 100 exceeds 3.0 Kw, the slave inverter is operated in parallel with one master inverter and the DC power exceeding it To perform AC power conversion. That is, the number of inverters to be driven is determined according to the magnitude of the DC power amount input to the inverter 300 side.

Fig. 3 shows a method of operating the above-described photovoltaic device. First, power generation power is supplied from at least one solar cell module (S10). The solar cell module generates power for generating electricity, that is, DC power, using energy absorbed from sunlight. The output DC power requires driving the inverter to convert to AC power. In order to efficiently select the inverter to be driven among the plurality of inverters provided, the solar power generation apparatus compares the cumulative power amount of the plurality of inverters connected in parallel (S30). According to the result of the comparison, the solar power generator sets the master inverter and the slave inverter respectively. Specifically, the inverter having the smallest accumulated power among the plurality of inverters is set as the master inverter (S40), and the remaining inverters are set as the slave inverters (S45). If there are a plurality of slave inverters, the necessary number of slave inverters are set in ascending order from the slave inverters having a small cumulative power amount. Then, it is determined whether the master inverter and the slave inverter are operated in parallel based on the amount of DC power output from the solar cell module. That is, it is determined whether the DC power amount exceeds the maximum allowable capacity of the master inverter (S50). If it is determined that the DC power amount is within the predetermined maximum allowable capacity of the master inverter, only the master inverter is driven alone (S55). If it is determined that the DC power amount exceeds the predetermined maximum allowable capacity of the master inverter, a part or all of the slave inverter is operated in parallel with the master inverter (S60). Here, the number of slave inverters driven in parallel with the master inverter is determined according to the amount of DC power output from the solar cell module. Whether the master inverter and the slave inverter operate in parallel or not is determined through the switching operation of the switches provided between the output terminal of the solar cell module and the input terminal of the plurality of inverters.

The photovoltaic device then drives the master inverter or the master inverter and the slave master to convert the DC power supplied from the solar cell module to AC power. The AC power is supplied to the load (S70).

In an embodiment, the method of operating the photovoltaic device may further include resetting the predetermined master inverter and the slave inverter according to the DC power amount and the driving time of the master inverter. Specifically, if the amount of DC power output from the solar cell module is larger than that in the previous drive, the required number of slave inverters can be additionally set. On the other hand, if the amount of DC power output from the solar cell module is smaller than that in the previous driving, the previously set slave inverter can be released. The additional connection or disconnection of the inverter is accomplished through the switching operation of the switches provided at the input terminal of the inverter unit. In addition, the control signals applied to the switches for the switching operation may be transmitted from the control unit 350 as described above, or may be generated and transmitted from the control module 350a connected to the master inverter. In the latter case, the driving of the slave inverter is implemented by the control module 350a of the master inverter.

When the drive time of the master inverter becomes longer, the cumulative power increases. Therefore, for example, it is possible to replace or reset the predetermined master inverter and the slave inverter by checking the driving time of the master inverter at predetermined time intervals or at each time when the drive stop control signal of the inverter alternates.

Also, in the embodiment, it is possible to monitor in real time whether the load is abnormal during the AC power supply. If it is determined that the load is in an abnormal state according to a predetermined criterion, the photovoltaic generator transmits a corresponding control signal to separate the inverter from the load. If it is determined that the load is in a normal state according to a predetermined criterion, the photovoltaic device may transmit a corresponding control signal to connect the inverter to the load.

As described above, according to the photovoltaic device and the method of operating the same according to the embodiment of the present invention, a plurality of parallel-connected inverters are connected and operated based on the amount of generated power output from the solar cell module, It is possible to generate power even when a failure occurs in any one of the plurality of inverters, thereby increasing the power supply efficiency. In addition, according to the solar cell power generation apparatus and the operation method thereof, unnecessary driving of the inverter is limited by setting and driving a plurality of parallel-connected inverters as a master inverter or a slave inverter according to accumulated power amount, thereby extending the life of the inverter. Furthermore, according to the solar cell power generation apparatus and the operation method thereof, it is sufficient to additionally connect as many inverters having the same capacity as the required number without separately installing an inverter having a large capacity even when the solar cell module is additionally provided. Installation cost is reduced.

100 - Solar module 200 - Switch
300 - Inverter 400 - Load
500 -

Claims (14)

At least one solar cell module;
A plurality of inverters for converting DC power of the solar cell module into AC power and supplying the AC power to a load;
A plurality of switches connecting the solar cell module to the inverter through a switching operation corresponding to a control signal; And
And a control unit for driving the inverter and generating the control signal based on a DC power amount of the solar cell module,
Wherein the plurality of inverters are connected in parallel with each other,
Wherein the control unit drives a part or all of the plurality of inverters in parallel based on a DC power amount output from the solar cell module,
Compares the cumulative power amount of each of the plurality of inverters, sets the master inverter and the slave inverter according to the comparison result,
Further setting a slave inverter when the amount of DC power is increased as compared with that in the previous driving, releasing a predetermined slave inverter when the amount of DC power is decreased from that in the previous driving,
And resetting the predetermined master inverter and the slave inverter by checking the driving time of the preset master inverter at a predetermined time interval. delete The method according to claim 1,
Wherein the plurality of switches are located between an output terminal of the solar cell module and an input terminal of the plurality of inverters, and each connects or disconnects the solar cell module and the inverter. The method according to claim 1,
Wherein the controller sets the master inverter as the smallest cumulative power amount among the plurality of inverters as a result of the comparison and sets the remaining one as the slave inverter. 5. The method of claim 4,
Wherein when the slave inverters are plural, a slave inverter is set in ascending order from slave inverters having a small cumulative power amount. The method according to claim 1,
Wherein the control unit operates the part or all of the master inverter and the slave inverter in parallel when the amount of DC power output from the solar cell module exceeds a predetermined allowable capacity of the master inverter. The method according to claim 1,
Wherein the plurality of inverters each include a control module connected to each other via at least one communication line, and the control module communicates with each other using an RS-485 communication protocol standard. The method according to claim 1,
Wherein,
And a control module corresponding to each of the master inverter and the slave inverter, and generates the control signal and the drive command of the plurality of inverters through a control module corresponding to the master inverter. Comparing accumulated power quantities of a plurality of inverters connected in parallel;
Setting a master inverter and a slave inverter according to the comparison result;
Determining whether the master inverter and the slave inverter are operated in parallel based on the amount of DC power output from the solar cell module;
Driving the selected inverter to convert the DC power of the solar cell module to AC power according to the determination; And
And supplying said AC power to a load,
Wherein the setting step comprises:
Comparing a cumulative power amount of each of the plurality of inverters, and setting a master inverter and a slave inverter according to the comparison result;
Further setting a slave inverter when the amount of DC power is increased as compared with that in a previous driving and releasing a predetermined slave inverter when the amount of DC power is reduced compared with a previous driving time; And
Further comprising the step of resetting the predetermined master inverter and the slave inverter by checking the driving time of the preset master inverter at a predetermined time interval. 10. The method of claim 9,
Wherein the setting step comprises:
Wherein the step of setting the smallest cumulative power amount among the plurality of inverters as a master inverter and the remaining one as a slave inverter is performed. 10. The method of claim 9,
Wherein the step of determining whether to perform the parallel operation includes:
Wherein the step of determining whether or not the master inverter and the slave inverter are operated in parallel through a switching operation of an output terminal of the solar cell module and an input terminal of the plurality of inverters. delete 10. The method of claim 9,
Wherein the supplying step comprises:
Monitoring the load in real time, disconnecting the inverter from the load if the load is determined to be abnormal according to a predetermined reference, and connecting the inverter to the load if the load is determined to be in a normal state according to a predetermined reference And operating the solar cell. 10. The method of claim 9,
Wherein the plurality of inverters each have a control module connected through one or more communication lines, and the control module communicates with each other using an RS-485 communication protocol standard.

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