KR101975756B1 - Solar power generation system with spare inverter for emergency response - Google Patents

Abstract

The present invention relates to a solar power generation system with a spare inverter for emergency response, which flexibly and rapidly copes with an inverter fault to be capable of enhancing efficiency of a solar power generation apparatus. To this end, the present invention provides the solar power generation system with the spare inverter for emergency response, comprising: a plurality of solar cell panels accumulating solar rays to generate electric energy; a plurality of inverters individually connected to the solar cell panels and converting power, transmitted in a direct current state from the solar cell panels, into power in an alternating current state; a distribution board provided with a breaker for blocking overcurrent and connected to each of the inverters; an inverter state information transceiving unit receiving and monitoring information on a plurality of states for operation states of the inverters transmitted by the inverters or transmitting state information on the inverters; a spare inverter operated in place of an inverter which transmits an error signal when one inverter among the plurality of the inverters transmits the error signal; and a spare inverter control unit positioned on and connected to a circuit between the solar cell panels and the inverters, receiving the state information of each of the inverters transmitted from the inverter state information transceiving unit to determine whether the spare inverter is operated, and transmits a driving signal, for driving the spare inverter, to the spare inverter.

Description

[0001] Solar power generation system with spare inverter for emergency response [0002]

The present invention relates to a solar power generation system equipped with a spare inverter for emergency response. More specifically, when any one of a plurality of inverters used for solar power generation transmits an error signal due to a failure or the like, a spare inverter capable of operating in place of the corresponding inverter is mounted to the inverter In order to operate the spare inverter flexibly, it monitors the status information of each inverter, classifies the error signal for each status information according to the importance, and checks whether the spare inverter is driven separately for each classified error signal. And the start time of the spare inverter can be set so that it is possible to easily identify the fault site in the event of an inverter failure and to provide an emergency response capable of improving the efficiency of the photovoltaic power generation device in response to the failure of the inverter more flexibly and promptly To a solar power generation system equipped with a spare inverter for .

Korea is highly dependent on oil and has low self-reliance on energy, so the government actively supports renewable energy projects such as solar energy, wind power, small hydro power, geothermal energy, marine energy and bio energy.

Photovoltaic power generation, which is one of power generation using renewable energy, is one of technologies to convert solar energy into electric energy using solar power generation system. .

Unlike conventional fossil energy sources, sunlight does not cause greenhouse gas emissions or environmental destruction, and solar radiation has the advantage of being endless.

The photovoltaic power generation system consists of a solar cell module that receives light and produces DC electricity, a battery to store the generated electricity, and an inverter PCS that converts DC electricity into AC electricity and connects it to the power system.

The main function of the inverter is to convert the DC electricity generated from the solar array into AC electricity and supply it to the system in accordance with the required voltage / frequency / phase, thereby maximizing the output of the solar array under various irradiation conditions.

Due to the nature of photovoltaic power generation, it is better to think of energy loss as a failure. The most frequent service frequency in PV systems is the inverter. And since the energy loss rate is also the highest, it can be considered that the inverter is also faulty.

However, it can be said that the inverter is the only product that displays the fault while operating in the PV system, which is less active than the service frequency.

The frequency of occurrence and the energy loss of the internal parts or elements of the inverter when the inverter is serviced is the most frequently occurring control program, followed by the control card / board, the AC contactor, the fan, IGBTs occur in descending order.

The frequent occurrence of service by the control program often means that the inverter is malfunctioning or stopped for no reason.

Accordingly, when a failure occurs in any one of a plurality of inverters used in photovoltaic power generation, it can be automatically replaced to prevent power loss due to the failure of the inverter, and it is possible to easily identify a failure site when an inverter failure occurs There is a need for a new system that can flexibly and quickly improve the efficiency of a photovoltaic device in response to failure of the inverter.

Prior Art Document: KR Patent Registration No. 10-1436019 (Bulletin of Sep. 1, 2014)

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems described above, and it is an object of the present invention to provide a solar power generating apparatus capable of replacing a corresponding inverter when one of the inverters used for solar power generation generates an error signal, By installing a spare inverter, it is possible to block the power loss caused by the faulty inverter. In order to operate the spare inverter flexibly, it monitors the status information of each inverter, classifies error signals for each status information according to the importance, It is possible to determine whether the spare inverter is driven separately for each signal or to set the drive start time of the spare inverter so that the fault site can be easily grasped in the event of an inverter failure and more flexible and quick For emergency response to improve the efficiency of the device And an object of the present invention is to provide a solar power generation system equipped with a spare inverter.

According to an aspect of the present invention, there is provided a photovoltaic generation system including a spare inverter for emergency response, comprising: a plurality of solar battery panels for collecting sunlight to generate electric energy; A plurality of inverters respectively connected to the respective solar panels and converting the power transmitted from the solar panels in a DC state into an AC state; A distribution board provided with a circuit breaker for blocking an overcurrent, and connected to each inverter; An inverter status information transmission / reception unit for receiving and monitoring a plurality of status information on the operating status of the inverter transmitted from the inverter or transmitting the status information of the inverter; A spare inverter that operates by replacing an inverter that transmits an error signal when any inverter of the plurality of inverters transmits an error signal; And a control unit connected to the circuit between the solar panel and the inverter for receiving the status information of each inverter transmitted from the inverter status information transmitting and receiving unit to determine whether the spare inverter is in operation and outputting a driving signal for driving the spare inverter And a spare inverter control unit for transmitting the spare inverter control signal to the spare inverter.

In addition, the spare inverters are individually branched in a circuit line connecting a plurality of solar panels and a plurality of inverters, and are connected in parallel with a plurality of inverters, and one inverter transmits one or more error signals to inverter status information transmission / And the spare inverter control unit receiving the error signal from the inverter status information transmitting and receiving unit interrupts the operation of the corresponding inverter for transmitting the error signal and transmits the error signal to the spare inverter circuit, . ≪ / RTI >

In addition, in the spare inverter control unit, error signals for each state information of the inverter transmitted from the inverter state information transmitting and receiving unit are classified and stored according to the importance, and the operation of the spare inverter or the operation of the spare inverter And can set a waiting time.

According to the present invention, power loss due to a faulty inverter can be prevented.

In addition, there is an effect that a fault site of the inverter can be easily grasped when an inverter fault occurs.

Further, there is an effect that the efficiency of the photovoltaic power generation apparatus can be improved by flexibly and promptly responding to occurrence of an inverter failure.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing the overall configuration of a photovoltaic power generation system equipped with a spare inverter for emergency response according to a preferred embodiment of the present invention;
2 is a view showing a connection state between a solar cell panel, a spare inverter control unit, an inverter, a spare inverter, and a distribution board,
3 is a view showing a connection state of the solar cell panel and the inverter and the spare inverter,
4 is a view showing a lamp-type switch and a monitoring terminal connection unit provided in the spare inverter control unit.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the preferred embodiments of the present invention will be described below, but it is needless to say that the technical idea of the present invention is not limited thereto and can be variously modified by those skilled in the art.

FIG. 1 is a block diagram showing the overall configuration of a solar power generation system including a spare inverter for emergency response according to a preferred embodiment of the present invention. FIG. 2 is a block diagram of a solar cell panel, a spare inverter control unit, an inverter, FIG. 3 is a view showing a connection state between the solar cell panel and the inverter and the spare inverter, and FIG. 4 is a view illustrating a connection between the lamp switch and the monitoring terminal in the spare inverter control unit.

1 to 3, a solar power generation system including a spare inverter for emergency response according to a preferred embodiment of the present invention includes a solar cell panel 10, an inverter 20, a distribution board 30, A status information transmission / reception unit 40, a spare inverter 50, a spare inverter control unit 60, and an integrated monitoring control unit 100.

First, in the solar photovoltaic generation system equipped with a spare inverter for emergency response according to the present invention, any inverter 20 among a plurality of inverters 20 used for solar power generation transmits an error signal due to a failure or the like It is possible to prevent the power loss due to the failure of the inverter 20 by mounting the spare inverter 50 that can operate in place of the inverter 20.

In order to operate the installed spare inverter 50 flexibly, error signals for a plurality of status information indicating the operating states of the inverters 20 are classified according to their importance, and the spare inverters 50 And the operation start time of the spare inverter 50 can be set so that the fault site can be easily grasped when the inverter 20 fails, and it is possible to more flexibly and promptly respond to the failure of the inverter 20, The efficiency of the apparatus can be improved.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, constituent elements of a photovoltaic power generation system equipped with a spare inverter for emergency response according to a preferred embodiment of the present invention will be described in detail.

Referring to FIG. 1 and FIG. 2, a plurality of solar panels 10 are independently constructed, and solar energy is accumulated to generate electric energy.

Referring to FIGS. 1 and 3, a plurality of inverters 20 are connected to the solar cell panels 10, respectively, and convert the electric power transmitted in the DC state into the AC state in the solar cell panel 10.

Referring to FIG. 3, the distribution board 30 is connected to each inverter 20 and is connected to a grid-connected system, that is, a system for receiving electric power produced by linking a solar power generation facility with a KEPCO, A branch circuit and an overcurrent breaker for overcurrent shutdown are provided.

1, a terminal capable of collecting status information of the inverter 20 and transmitting the status information of the inverter 20 to an external device, including a data acquisition system, a PC, and a tablet PC, may be used. The inverter 20 receives a plurality of state information indicating the operating state of the inverter 20 including the voltage and current of the inverter 20 transmitted from the inverter 20 and displays it so that the operator can monitor the state information. And transmits the status information to the spare inverter control unit 60 described below.

If any one of the inverters 20 among the plurality of inverters 20 in the operating state transmits one or more error signals to the inverter status information transmitting and receiving unit 40, the inverter 20 will switch to the spare The inverter 50 is replaced.

At this time, when the spare inverter 50 is operated, status information on the operating state of the spare inverter 50 is also transmitted and received by the inverter state information transmission unit 40.

Referring to FIGS. 1 and 2, the spare inverter 50 includes one of the plurality of inverters 20, one of the status information indicating the operation status of the inverter 20, In the case where the above-mentioned state information transmits an error signal out of the operating range of the normal state, it is configured in parallel with other inverters 20 in order to replace and operate the corresponding inverter 20 transmitting the error signal.

3, the spare inverter 50 is branched individually in a circuit line connecting a plurality of solar cell panels 10 and a plurality of inverters 20 and connected in parallel with a plurality of inverters 20, It is connected as an enemy.

Referring to FIGS. 1 and 2, the spare inverter control unit 60 may be embodied as an embedded program by a PLC or a microprocessor. The spare inverter control unit 60 may include a solar cell 10 and an inverter 20 including a spare inverter 50 And is connected to the circuit.

The spare inverter control unit 60 receives status information of each inverter 20 transmitted from the inverter status information transmission and reception unit 40 to determine whether the spare inverter 50 is operating, And transmits the driving signal to the spare inverter (50).

The spare inverter control unit 60 receives the status information of each inverter 20 transmitted from the inverter status information transmitting and receiving unit 40 and when any inverter 20 of the plurality of inverters 20 transmits an error signal , The spare inverter control unit 60 cuts off the operation of the inverter 20 that transmits the error signal and sends the inverter 20 that transfers the error signal by automatically branching to the spare inverter 50 circuit to the spare inverter 50 Will be replaced.

In addition, in the spare inverter control unit 60, the state information of each inverter 20 transmitted by the inverter state information transmitting and receiving unit 40 and the error signal for each state information are classified and stored according to their importance, It is possible to individually set whether to operate the spare inverter 50 or wait time for operating the spare inverter 50. [

Specifically, when the inverter control unit 60 receives an error signal among the status information of the inverters 20 transmitted from the inverter status information transmitting and receiving unit 40, the error signal is transmitted to the spare inverter 50 The operation of the inverter 20 which has transmitted the error signal without waiting time for operating the spare inverter 50 is stopped and the operation of the spare inverter 50 is stopped Operate immediately.

If the error signal is one of the error signals classified as an error signal that should be waited for a predetermined time for starting the operation of the spare inverter 50 after the spare inverter control unit 60 receives the error signal, After waiting, it is determined whether the same error signal is continuously transmitted from the inverter 20 again to accumulate over several times, and then it is determined whether or not the spare inverter 50 is operating.

That is, if an error signal is continuously transmitted even after waiting for a predetermined time, the operation of the inverter 20 for transmitting an error signal is interrupted, and the spare inverter 50 is operated. If the error signal transmitted from the inverter 20 after returning to the normal state signal after waiting the predetermined waiting time, the spare inverter 50 is not operated.

If the error signal transmitted through the inverter status information transmitting / receiving unit 40 is one of the error signals that do not operate the spare inverter 50, the spare inverter control unit 60 controls the spare inverter 50 The inverter 20 that has transmitted the error signal and the AC circuit breaker of the inverter 20 located in the distribution board 40 are shut off so that only the remaining inverters 20 except for the inverter 20, Driving.

The reason why the error signal of the inverter 20 is classified and the spare inverter 50 is operated and the standby time is set separately for starting the operation of the spare inverter 50 is that, There may be a case where the operation unit 20 operates abnormally due to a temporary error when it operates. In this case, when the predetermined time elapses, the error factor is naturally removed and the error signal is restored to the normal state signal. Therefore, there is no need to operate the spare inverter 50 and a very serious failure occurs in the inverter 20, The operator visits the site directly to diagnose the fault and immediately responds to the fault. In this case, the inverter 20 is operated only by the remaining inverter 20 without operating the spare inverter 50 This is because it is necessary to respond urgently.

A plurality of state information corresponding to the normal operating state of the inverter 20 is previously inputted and stored in the spare inverter control unit 60. The state information of the inverter 20 received from the inverter state information transmitting and receiving unit 40 Error signals that determine whether the inverter 20 operates abnormally to operate the spare inverter 50 or require the standby time for the spare inverter 50 to operate include the following.

The PV overcurrent that the current flowing into the inverter 20 from the solar cell panel 10 exceeds a specified value, the PV sunbeam voltage that the voltage of the solar cell panel 10 is below or exceeds the specified value, Over-current of the inverter exceeds the specified value. Over-voltage of the system exceeds the specified value. Over-voltage of the system. Under-voltage of the system is below the specified value. System and frequency exceeding the specified value. System frequency lower than the specified value. Low frequency. Solar and power with less than the specified value of the input power. AC current with DC component of output current exceeding the specified value. DC component. DC wiring leakage, Insulation resistance error below insulation resistance, AC N phase connection incorrect AC phase connection error, etc. All.

4, an initialization switch 62, a mode selection switch 64, a spare inverter operation switch 66, and a plurality of inverter failure switches 67 are connected to the spare inverter control unit 60 And a monitoring terminal connection part 68 are provided.

Here, the initialization switch 62 is a switch for initializing the entire system operation including stopping the operation of the spare inverter 50 when the spare inverter 50 is in operation, and when the spare switch is pressed for a few seconds, the lamp is turned on When the initialization is completed, the lamp is turned off.

The mode selection switch 64 allows the spare inverter 50 to be automatically operated by the spare inverter control 60 or to select the automatic or manual mode so that the operator can operate it manually.

The spare inverter operation switch 66 is operated by the operator manually operating the spare inverter 50 when the manual operation mode is selected in the mode selection switch 64 and the inverter 20 which transmits an error signal among the plurality of inverters 20, The lamp of the spare inverter operation switch 66 is turned on and the lamp of the spare inverter operation switch 66 is turned on when the spare inverter operation switch 66 is pressed and operated.

The plurality of inverter error switches 67 are switches that can be used when the operator manually operates the spare inverter 50. The inverter 20 is provided for each inverter 20 and includes an inverter 20 for transmitting an error signal among the plurality of inverters, The inverter 20 is in the error mode state when the corresponding inverter fault switch 67 of the inverter 20 in which the error has occurred is displayed and the error signal The operation of the inverter 20 for transmitting the inverter fault switch 67 is stopped, and the inverter fault switch 67 causes the lamp to be turned on.

The monitoring terminal connection unit 68 is an interface for connecting a monitoring terminal including a portable touch pendant for monitoring the communication status between the inverter status information transmission / reception unit 40 and the spare inverter control unit 60.

1, a wireless communication unit (not shown) including a Wi-Fi is connected to the inverter status information transmission / reception unit 40 or the spare inverter control unit 60 through which status information of the inverter 20 or the spare inverter 50 is transmitted / received Information on the operation stop state of the faulty inverter 20, the operation of the spare inverter 50, and the operation state information of the inverter 20 or the spare inverter 50, to the integrated monitoring control unit 100 And the integrated monitoring and control unit 100 may monitor the operation status of the inverter 20 or the spare inverter 50 by receiving the corresponding information.

In addition, the information transmitted through the wireless communication unit is transmitted in a notification message including the SNS through the smart device 200 of the remote worker, so that the information can be quickly responded to an emergency.

It will be apparent to those skilled in the art that various modifications, substitutions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10 - Solar panel 20 - Inverter
30 - Distribution board 40 - Inverter status information transmission /
50 - Spare Inverter 60 - Spare Inverter Control
100 - Integrated Monitoring and Control Department

Claims (3)

A plurality of solar cell panels for collecting sunlight to generate electric energy;
A plurality of inverters respectively connected to the respective solar panels and converting the power transmitted from the solar panels in a DC state into an AC state;
A distribution board provided with a circuit breaker for blocking an overcurrent, and connected to each inverter;
An inverter status information transmission / reception unit for receiving and monitoring a plurality of status information on the operating status of the inverter transmitted from the inverter or transmitting the status information of the inverter;
A spare inverter that operates by replacing an inverter that transmits an error signal when any inverter of the plurality of inverters transmits an error signal; And
Receiving the status information of each inverter transmitted from the inverter status information transmitting and receiving unit to determine whether the spare inverter is in operation, and outputting a driving signal for driving the spare inverter to the spare Spare inverter control to transfer to inverter
Lt; / RTI >
A spare inverter is branched in a circuit line connecting a plurality of solar panels and a plurality of inverters, and is connected in parallel with a plurality of inverters. One inverter transmits one or more error signals to the inverter status information transmitting and receiving unit And the spare inverter control unit receiving the error signal from the inverter status information transmitting and receiving unit interrupts the operation of the corresponding inverter for transmitting the error signal and substitutes the inverter for transmitting the error signal by automatically branching to the spare inverter circuit To do
/ RTI >
In the spare inverter control unit, error signals for each state information of the inverters transmitted from the inverter state information transmitting and receiving unit are classified and stored according to their importance, and a waiting time for operating the spare inverters individually or for operating the spare inverters Can be set
/ RTI >
In the spare inverter control unit, when an error signal is transmitted among the status information of each inverter transmitted from the inverter status information transmitting and receiving unit and the error signal is one of the error signals classified as an error signal that must immediately operate the spare inverter, It stops the operation of the inverter that sent the error signal without waiting time to operate the spare inverter, immediately activates the spare inverter, If the error signal is one of the error signals classified as an error signal that should wait for a predetermined time for starting the operation of the spare inverter after the spare inverter controller receives the error signal, the error signal is received and waits for a predetermined time, If the error signal transmitted from the inverter is restored to the normal state signal after waiting for the predetermined waiting time, it is determined whether the spare inverter is operated, Not operating the inverter
/ RTI >
In the spare inverter control unit, when the error signal transmitted through the inverter status information transmitting / receiving unit is one of those classified as an error signal that does not operate the spare inverter, the spare inverter is not operated and the remaining inverters except for the inverter, To drive with only
And a spare inverter for an emergency response. delete delete

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