CN111146810A - Three-phase grid-connected cascade photovoltaic inverter and optical fiber communication control method thereof - Google Patents

Abstract

The invention discloses a three-phase grid-connected cascade photovoltaic inverter and a communication control method thereof, which are characterized by comprising a power unit part and a main controller part, wherein the power unit part is a cascade inversion array consisting of 18 power unit modules (PMUs); the main controller part comprises a main control panel (MU), an analog quantity panel (AU) and a digital quantity panel (DU), and the input end of each PMU is connected with a photovoltaic panel unit body to form a small photovoltaic inverter system. The invention has the advantages of high voltage grade, large power grade, stable performance and the like, and can directly carry out high-voltage grid connection without a transformer.

Description

Three-phase grid-connected cascade photovoltaic inverter and optical fiber communication control method thereof

Technical Field

The invention relates to a three-phase grid-connected cascade photovoltaic inverter and an optical fiber communication control method thereof, belonging to the field of optical fiber communication.

Background

Solar power generation is a clean and efficient power generation mode, and solar energy is safe, general, large in quantity, inexhaustible and inexhaustible. Photovoltaic inversion is one of the most important means for obtaining solar energy. The cascade photovoltaic inverter is formed by cascading a plurality of independent photovoltaic inverters, the inverters need to work cooperatively, and a good communication technology is a premise for controlling each photovoltaic inverter unit, so that the control of each unit photovoltaic inverter needs to be strengthened.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: how to design a three-phase grid-connected cascade photovoltaic inverter system to solve the demand of photovoltaic power generation, and simultaneously, the three-phase grid-connected cascade photovoltaic inverter system has the characteristics of high voltage level, large power level, stable performance and capability of directly carrying out high-voltage grid connection without a transformer.

In order to solve the technical problem, the technical scheme of the invention is to provide a three-phase grid-connected cascade photovoltaic inverter which is characterized by comprising a power unit part and a main controller part, wherein the power unit part is a cascade inversion array consisting of 18 power unit modules (PMUs); the main controller part comprises a main control panel (MU), an analog quantity panel (AU) and a digital quantity panel (DU), and the input end of each PMU is connected with a photovoltaic panel unit body to form a small photovoltaic inverter system.

Preferably, the PMU comprises a Boost voltage boosting circuit and an H-bridge inverter circuit; the H-bridge inverter circuit consists of four switching tubes with anti-parallel diodes, the switching tubes and the switching tubes of the Boost circuit are 5 switching tubes in total, each PMU adopts DSP and FPGA as processors to process data and control the 5 switching tubes, the photovoltaic panel unit bodies are connected to the input end of the Boost circuit, and the output end of the Boost circuit is connected to the input end of the H-bridge inverter circuit; output sides of H-bridge inverter circuits of the PMUs are connected in series two by two, 3 groups of inverters connected in series adopt star connection to form a three-phase circuit and are merged into a power grid, and each phase is connected into one phase of the power grid through a reactor.

Preferably, the main controller part comprises a main control board (MU), three analog boards (AU1, AU2 and AU3) and a digital board (DU), wherein the three AU boards measure the grid voltage, the inverter output voltage and the inverter output current respectively.

Preferably, the main control board (MU) adopts DSP and FPGA as a processor to process data, wherein the DSP performs algorithm processing; the FPGA and the outside are subjected to interface control, and all optical fiber communications are connected to the FPGA for processing.

Preferably, the three analog quantity boards (AU1, AU2 and AU3) respectively collect three-phase voltage of a power grid, three-phase voltage output by the whole inverter and three-phase current output by the whole inverter and send signals to the MU through optical fiber communication, the signals are put into the SRAM by the FPGA of the MU, then the signals are read by the DSP, and corresponding operations are executed by DSP software.

Preferably, the digital volume board DU is in fiber communication with the MU, the MU transmits a Digital Output (DO) signal to the DU, and the DU transmits a Digital Input (DI) signal to the MU.

The invention also provides an optical fiber communication control method of the three-phase grid-connected cascade photovoltaic inverter, which is characterized by comprising a main control board (MU), a power unit module (PMU), an analog quantity board (AU) and a digital quantity board (DU), wherein the analog quantity board (AU) collects each analog quantity, analog-digital conversion signals are sent to the main control board (MU) through optical fiber communication, the digital quantity board (DU) is in optical fiber communication with the main control board (MU), receives digital quantity output signals and sends digital quantity input signals to the main control board (MU), each PMU is in optical fiber communication with the main control board (MU), receives main control instructions and sends unit states to a main controller.

Preferably, the PMU collects voltage and current of the unit photovoltaic panel and bus voltage output by the Boost circuit, maximum power point tracking MPPT is achieved by controlling the Boost chopper switch, unit states such as the voltage and the current of the unit photovoltaic panel and the bus voltage output by the Boost circuit are sent to the MU through optical fiber communication, the MU sends sine pulse width comparison values of all phases to the PMUs through optical fiber communication according to corresponding phases, and the PMU performs phase shift carrier control according to the received sine pulse width comparison values and the current PMU in-phase cascade position, so that an H-bridge inverter circuit of the PMU outputs pulse width modulation voltage to achieve cascade grid-connected control.

The invention provides a three-phase grid-connected cascade photovoltaic inverter and an optical fiber communication control method thereof, which are used for meeting the requirements of photovoltaic power generation, have the advantages of high voltage level, high power level, stable performance and the like, can be directly used for high-voltage grid connection without a transformer, and save the cost and the space occupation.

Drawings

FIG. 1 is a diagram of a connection structure of a photovoltaic panel unit body and a PMU;

FIG. 2 is a cascaded grid-connected graph of cascaded photovoltaic inverters;

FIG. 3 is a communication structure diagram of a cascaded photovoltaic inverter;

FIG. 4 is a flowchart of DU and MU communication;

FIG. 5 is a flowchart of AU and MU communication;

FIG. 6 is a flow chart of MU-PMU communication;

FIG. 7 is a signaling diagram of the MU and the PUM;

fig. 8 is a flowchart of the entire system.

Detailed Description

In order to make the invention more comprehensible, preferred embodiments are described in detail below with reference to the accompanying drawings.

As shown in fig. 1 to 8, the main structure of the three-phase grid-connected cascade photovoltaic inverter includes two parts, namely a power unit and a main controller; the power unit part is a cascade inversion array consisting of 18 power unit modules (PMUs); the main controller part comprises a main control board (MU), three analog boards (AU1, AU2 and AU3) and a digital board (DU). The MU is controlled by DSP (F28M35) and FPGA (EP4CE10F17C 8).

As shown in fig. 1, each power unit module is an individual photovoltaic inverter, and includes a Boost voltage Boost circuit and an H-bridge inverter circuit; the inverter circuit consists of four switching tubes with anti-parallel diodes, and the number of the switching tubes is 5 in total together with the switching tubes of the Boost circuit. Each PMU uses a DSP (TMS320F28035) and an FPGA (EP4CE6F17C8) as processors to perform data processing and control 5 switching tubes. The photovoltaic panel unit body is connected to the input end of the Boost circuit, and the output end of the Boost circuit is connected to the input end of the H-bridge inverter circuit; the voltage obtained by the photovoltaic panel unit bodies is boosted through a Boost circuit and inverted through an H-bridge inverter circuit. As shown in fig. 2, the output sides of the H-bridge inverter circuits of the plural PMUs are connected in series two by two, 3 groups of inverters connected in series are connected in a star-like manner to form a three-phase circuit, and are merged into a power grid, and each phase is connected to one phase of the power grid through a reactor.

The communication structure diagram in the system is shown in figure 3, and comprises AU, DU, PMU and MU optical fiber communication, wherein the optical fiber communication baud rate is set to be 2Mbps, and 8-bit data is transmitted each time. Each 8-bit data is accompanied by a start bit, a parity bit and a stop bit, and 11-bit data is transmitted each time, the transmission time being 5.5 us.

Referring to fig. 4, three AU boards are provided, AU1 measures the voltage of a power grid, AU2 measures the voltage of three phases output by an inverter, AU3 measures the current of three phases output by the inverter, the electric signals are sent to MU through optical fiber communication, an FPGA of the MU board puts the signals into an SRAM, then a DSP reads the signals, and then DSP software executes corresponding operation.

As shown in fig. 5, the DU performs optical fiber communication with the MU board, provides input signals such as start-up and shutdown for the MU board, and outputs operation state information of the MU, such as a normal operation state, a fault state, and an alarm state; digital quantity DI output by a button on the DU board enters the DU and is sent to the MU through an optical fiber, a DI signal is stored in the SRAM by the MU board FPGA, then the DI signal is read by the DSP, and corresponding operation is executed by the DSP software. The MU sends an operation state signal to the DU, the DU sends a digital quantity signal DO to the external indicating lamp, and the corresponding indicating lamp is lightened according to the operation state.

Each PMU carries out independent MPPT control, and the PMU gathers the voltage, the electric current of photovoltaic board unit body and the busbar voltage of Boost circuit output, realizes maximum power point tracking MPPT through controlling Boost chopper switch, sends unit states such as the voltage of photovoltaic board unit body, electric current and the busbar voltage of Boost circuit output for MU through fiber communication simultaneously. The MU board FPGA puts the signals into SRAM, then DSP reads the signals, and DSP software executes corresponding operation.

The MU board DSP calculates the three-phase sine pulse width comparison value and puts it into SRAM; and the MU board FPGA sends the sine pulse width comparison value of each phase to each PMU according to the corresponding phase through optical fiber communication, and the PMU performs phase-shifting carrier control according to the received sine pulse width comparison value and the current PMU in-phase cascade position, so that an H-bridge inverter circuit of the PMU outputs Pulse Width Modulation (PWM) voltage, and cascade grid-connected control is realized.

During grid-connected control, data sent to the PMU by the MU each time is a 16-bit sine pulse width comparison value (the upper 3 bits are 000, the lower 13 bits are effective) and a 16-bit CRC check value, 32 bits of data are sent in 4 times, 8 bits are sent each time, 8 bits of data sent each time are accompanied by a start bit, a parity check bit and a stop bit, the time of sending each time is 5.5us, and the time duration of sending 4 times is 22 us.

As shown in fig. 7, each actual data string is 11 bits, a 12-bit low-level signal of 6us is set as a synchronization header, and after sending the synchronization header, 2us is waited to send a 22us data signal, and one data transmission is completed. The interval between the two transmissions is: 50us (20 kHz). The MU sends a signal to the PMU.

The FPGA on the unit body generates symmetrical PWM waveforms by adopting an up-down counting comparison mode, the period of each PWM is 100us, and the frequency is 10 kHz. The clock frequency of the counts was 10k (3000 x 2) to 60 MHz. Using a carrier phase shifting technique, the modulated waves in the individual photovoltaic inverters of each phase are separated by one sixth of a cycle to reduce harmonics on the phases.

Claims (8)

1. A three-phase grid-connected cascade photovoltaic inverter is characterized by comprising a power unit part and a main controller part, wherein the power unit part is a cascade inversion array consisting of 18 power unit modules (PMUs); the main controller part comprises a main control panel (MU), an analog quantity panel (AU) and a digital quantity panel (DU), and the input end of each PMU is connected with a photovoltaic panel unit body to form a small photovoltaic inverter system.

2. The three-phase grid-connected cascade photovoltaic inverter as claimed in claim 1, wherein the PMU comprises a Boost circuit and an H-bridge inverter circuit; the H-bridge inverter circuit consists of four switching tubes with anti-parallel diodes, the switching tubes and the switching tubes of the Boost circuit are 5 switching tubes in total, each PMU adopts DSP and FPGA as processors to process data and control the 5 switching tubes, the photovoltaic panel unit bodies are connected to the input end of the Boost circuit, and the output end of the Boost circuit is connected to the input end of the H-bridge inverter circuit; output sides of H-bridge inverter circuits of the PMUs are connected in series two by two, 3 groups of inverters connected in series adopt star connection to form a three-phase circuit and are merged into a power grid, and each phase is connected into one phase of the power grid through a reactor.

3. A three-phase grid-connected cascade photovoltaic inverter as claimed in claim 1, characterized in that the main controller part comprises a main control board (MU), three analog boards (AU1, AU2 and AU3) and a digital board (DU), three AU boards measuring the grid voltage, the inverter output voltage and the inverter output current respectively.

4. The three-phase grid-connected cascade photovoltaic inverter as claimed in claim 1, wherein the main control board (MU) employs DSP and FPGA as processors for data processing, wherein the DSP performs algorithm processing; the FPGA and the outside are subjected to interface control, and all optical fiber communications are connected to the FPGA for processing.

5. The three-phase grid-connected cascade photovoltaic inverter as claimed in claim 3, wherein the three analog boards (AU1, AU2 and AU3) respectively collect three-phase voltage of a power grid, output three-phase voltage of the whole inverter and output three-phase current of the whole inverter, and send signals to the MU through optical fiber communication, the FPGA of the MU puts the signals into the SRAM, the DSP reads the signals, and the DSP software executes corresponding operations.

6. The three-phase grid-connected cascade photovoltaic inverter as claimed in claim 1, wherein the digital quantity board DU is in fiber-optic communication with the MU, the MU sends a digital quantity output (DO) signal to the DU, and the DU sends a digital quantity input (DI) signal to the MU.

7. The utility model provides a three-phase is incorporated into power networks and is cascaded photovoltaic inverter's optical fiber communication control method, a serial communication port, including main control panel (MU), power unit module (PMU), analog quantity board (AU) and digital quantity board (DU), analog quantity board (AU) gathers each analog quantity, send analog-to-digital conversion signal to main control panel (MU) through optical fiber communication, digital quantity board (DU) carries out optical fiber communication with main control panel (MU), receive digital quantity output signal, and send digital quantity input signal to main control panel (MU), each PMU carries out optical fiber communication with main control panel (MU), receive master control instruction, and send the unit state to the master control.

8. The method as claimed in claim 7, wherein the PMU collects a voltage and a current of the unit of the photovoltaic panel and a bus voltage output by the Boost circuit, controls the Boost chopper switch to realize the MPPT, and simultaneously transmits unit states of the voltage, the current, the bus voltage output by the Boost circuit, and the like of the unit of the photovoltaic panel to the MU through optical fiber communication, the MU transmits a sine pulse width comparison value of each phase to each PMU through optical fiber communication, and the PMU performs phase shift carrier control according to the received sine pulse width comparison value and a current PMU in-phase cascade position, so that an H-bridge inverter of the PMU outputs a Pulse Width Modulation (PWM) voltage to realize the cascade control.

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