KR101591575B1 - Combined wire-wireless type Solar smarter box using multiple power - Google Patents

Abstract

The present invention relates to a photovoltaic monitoring system capable of wired / wireless interface communication, and it provides information regardless of the operation state of the inverter and the power generation amount of the inverter by using the internet network and the mobile phone without directly visiting the operation status of the inverter .
To this end, data is received via PLC communication or serial communication (RS-485, RS-232) between the solar monitoring device (SSB) and the inverter, and SSB To effectively show the state of power generation.

Description

[0001] The present invention relates to an integrated photovoltaic (PV)

The present invention is for realizing a PV power monitoring system using a power generated by an inverter. The inverter generates PV power generated by the inverter through the PLC communication or RS485 communication between the inverter and the PV monitoring device, It is to provide power generation companies effectively.

As one of the measures to activate renewable energy, photovoltaic power generation system is attracting attention and the system that can manage it is solar photovoltaic monitoring device.

On the other hand, most of inverters connected to PV equipment are located in remote places, so it is difficult to check the operation status or failure status immediately, and there are many restrictions on access. Conventionally, the solar monitoring system is managed based on the grid-connected large-capacity inverter, and the monitoring is hardly performed for the module inverter and the small-capacity inverter of less than 5 Kw. Nowadays, it is becoming a trend to pursue large-scale power generation by using a small-capacity inverter that is convenient to operate and manage compared to a large capacity. Therefore, efficient management of the photovoltaic power generation is required and a monitoring device suitable for the low-

As one of the measures to activate renewable energy, photovoltaic power generation system is attracting attention and the system that can manage it is solar photovoltaic monitoring device.

On the other hand, most of inverters connected to PV equipment are located in remote places, so it is difficult to check the operation status or failure status immediately, and there are many restrictions on access. Conventionally, the solar monitoring system is managed based on the grid-connected large-capacity inverter, and the monitoring is hardly performed for the module inverter and the small-capacity inverter of less than 5 Kw. Nowadays, it is becoming a trend to pursue large-scale power generation by using a small-capacity inverter that is convenient to operate and manage compared to a large capacity. Therefore, efficient management of the photovoltaic power generation is required and a monitoring device suitable for the low-

Wired and wireless multi-power integrated photovoltaic for achieving the above object by the present invention The monitoring system is configured as shown in FIG. In order to manage the solar photovoltaic system, the power controller of FIG. When the inverter power is stabilized, the CPU makes a system diagnosis

It confirms the necessary information through the WAN and is configured to receive the power status data of each inverter using PLC communication.

In the case of module inverter, PLC communication is done by using power line, so it is sensitive to external power line noise, so LC filter is supplemented to AC coupling part so that data packet of module inverter can be normally received from external noise.

In the case of an inverter that performs serial communication, a circuit is configured in a daisy chain manner to manage multiple inverters with one serial port. In case of communication using a wireless network, the inverter transmits information of the inverter to RF Thereby confirming the normal operation state of the system.

Since the inverter operates only during the daytime, it configures a power control unit to supply stable power to the system and to prevent malfunction due to power supply disconnection. The MCU judges the power quality state provided by the inverter and cuts off the power output It includes a function that allows the server to operate reliably and a circuit that completely cuts off system power at night.

All of the above data is displayed on the system Google map, and the subscriber information is transmitted to the server and provided to the administrator.

The wired / wireless integrated photovoltaic The monitoring system enables the power generation company to install the solar power generation facility and monitor the current generation status stored in the server through the mobile phone or the Internet in real time by time, month, and year without visiting the site. In addition, system power can be cut off because the inverter power is maximized without an external power source.

1 is a block diagram of a system according to an embodiment of the present invention;
2 Detailed block diagram
3 Power supply control block diagram
4 flowchart

As an example of a whole implementation method for implementing the present invention, as shown in FIG. 1 , a wired / wireless integrated photovoltaic Power generation monitoring device .

2 to carry out this, wired and wireless integrated solar Using multiple power A detailed diagram for implementing the power generation monitoring device (SSB).

The USB (201) terminal is composed of two terminals, which can be used for data backup or upgrade using a USB memory, and serial communication is possible using a USB port.

The LCD display device 202 receives the data from the CPU 207 and checks the connection state between the current SSB and the inverter, the inverter connection number, the current power generation amount, the cumulative power generation amount, the voltage current, the frequency, the power, the Co2 reduction, .

The SD unit 200 plays a role of storing the SSB ID, password, subscriber information, information necessary for maintenance, and DB for SSB, which are necessary for operation with the server.

The PLC 1 block 208 has different characteristics according to the current manufacturer and has different frequency bands depending on the country. The low-speed PLC communication method of European type is C-BAN 132 KHz, BIT RATE 5.4 Kbps, and A-BAND is 86 KHz , And a bit rate of 3.6 kbps. In consideration of the number of such cases, the SSB can provide the inverter information to the CPU only by changing the PLC module such as the inverter when the PLC module is different in order to communicate with the module built in the inverter and the PLC. Therefore, in order to communicate by DC PLC method, PLC communication can be done by only changing the coupling filter part. Also, the PLC2 (28) block is composed of 29 common data pins so that it can be linked with the CPU through PLC communication in order to link with the same manufacturer PLC module applied to the inverter according to the manufacturer.

The ZIGBEE (203) or WIFI (204) is structured such that the RF module can be selectively operated in conjunction with the SSB in accordance with the inverter manufacturer. This is to apply various kinds of RF modules to one main board since the inverter will mainly use commercial products. In Europe and the Middle East, since it operates using the GSM (205) communication method, it is possible to transmit data using the GSM method by changing the interface module.

The Ethernet switch 209 configures one to four ports 210 to enable SSB 1: N network configuration by PC operation, camera application for on-site surveillance, and cleanness function.

 The MIN MCU (215) is connected to the server by the 10 / 100B Ethernet method and periodically communicates with the server, and records the subscriber account registration, system type, SSB quantity, inverter type, PV module type, PV quantity, Subscriber information, e-mail, and the like. In addition, the data transmitted from the MINI MCU is analyzed and the data is provided to the server in real time to output the amount of power by hour, day, month and year as a graph and an Excel file. The data provided by the MCU will also provide configuration information related to the system operation to show the subscribers, groups, and generals in the server. In addition, the MCU is implemented as a gateway function, which enables Ethernet communication, PLC communication, serial communication and USB serial communication function to the external Internet network by using the wired network, and also functions as a wireless gateway by using a wireless GSM network .

In the following, the basic data packet frame for the SSB to exchange information with the inverter consists of 20 bytes of Rx data packet as shown in Table 1, and 29 bytes of transmission packet in Table 2.

Table 1. SSB <-> Inverter RX packet frame configuration

Table 2. SSB <-> Inverter TX communication packet frame (inverter -> SSB) 29 bytes

 Table 3 shows an example of frame format for SSB to 1: N communication with several inverters.

Serial RS-485 (213) is a table for sending and receiving inverter power data by RS-485 1: N serial communication method between MCU and low capacity inverter. The SSB and the inverter check the inverter information by searching for the preset ID.

The power meter 214 is composed of a latch type relay and a shunt sensor for measuring the power consumed by the load in order to control the streetlight control or other necessary AC electrical system using SSB, And it is designed to be able to control electric devices at

The MINI MCU 215 exchanges necessary information with the CPU 207 using the Rx / Tx line. The mini MCU is configured to be used as a sub-board on the main board so that the mini MCU can be detached and attached according to system performance.

The power control unit 211 of FIG. 2 is shown in detail separately in FIG. 3, a USB DC / DC 301 unit, a PLC AC / DC unit 302, a system AC / DC unit 303, a backflow prevention element unit 304, a power selection unit 306, 305, a power output control unit 309, a power output unit 307, and a CPU 308. The USB DC / DC part is to supply the power supplied from the PC to the power required for SSB operation. The PLC AC / DC section is used to supply the power required for SSB operation using the power supplied from the module inverter. SYSTEM The AC / DC section is for supplying power to SSB by using KEPCO power when there is no external power source. Therefore, the SSB uses the power generated by the solar inverter in the power supply for the operation, but in some cases, the USB power source connected to the computer is used or the power source of the KEPCO is selected.

The MCU checks whether the power state signals D0, D1, and D2 are normal, and becomes a reference for selection. However, if the inverter generates a small amount of power or if power is cut off at night, SSB operation will stop and SSB may be recognized as a device malfunction in the server, or unnecessary information may be transmitted to the server. Information D1 is checked, S2 is controlled to shut off SSB power, and S3 signal of MCU is provided by CPU to prevent SSB malfunction in the server.

The backflow prevention device consists of a Schottky diode device to prevent power backflow from the SSB to the USB port or the inverter and to prevent power loss in the power supply line.

The power output control unit 309 receives the S2 signal and turns on / off the Y0 power.

FIG. 4 is a system flowchart showing the power information output from the SSB when the normal power is supplied from the power output controller. SSB analyzes the MIC PLC information or 3KW power information as shown in Table 3 before responding to the data request from the server. In addition, the inverter 1: N inverter is connected to check whether the inverters are normal and faulty. In this case, the SSB needs to be configured with an IP address, a port number, and an ID / PW in advance so that the SSB can be connected remotely. SSB analyzes power by real-time, daily, monthly and yearly and stores it as graph output and Excel file. It is provided to server and displayed on LCD window of SSB. SSB power information is managed by subscribers by server.

MIC (Micro Inverter Controller)
PLC (Power Line Communication)
PCS (Power Conditioning System)
SSB (Solar Smarter Box)
LCD: 8 * 2 display
Global System for Mobile Communications (GSM)
ZIGBEE: IEEE 802.15.4
WiFi (Wireless Fidelity): IEEE 802.11b
USB (Universal Serial Bus)

Claims (4)

A solar photovoltaic monitoring device for checking the state of solar power generation,
The solar monitoring apparatus comprises:
A PLC block that provides the module inverter information to the CPU through PLC communication in conjunction with the module inverter;
RS-485 serial RS-485 that provides low-capacity inverter information to MCU through serial communication in conjunction with low-capacity inverter;
An SD unit for storing information including an ID and a password of the PV monitoring apparatus;
An LCD display device receiving data from the CPU and displaying power information including the current generation amount of the inverter;
MCU for periodically communicating with the server; And
And a power control unit for controlling the power supply,
The power control unit includes a USB DC / DC unit for supplying power supplied from a PC;
A PLC AC / DC unit for supplying power supplied from the module inverter;
A SYSTEM AC / DC unit for supplying power using a KEPCO power source;
A power selection unit for selecting one of the USB DC / DC unit, the PLC AC / DC unit, and the SYSTEM AC / DC unit to supply power;
A power output control unit for turning on or off the power from the power source selection unit;
And a MCU for checking the status information of the PLC AC / DC unit and transmitting a signal to the power output control unit to shut off the power of the solar monitoring device.
The method according to claim 1,
Wherein the power control unit comprises a backflow preventing device for preventing a backflow of power from the solar monitoring device to the inverter. delete delete

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