EP2218170A1 - Solar inverter having a plurality of individual inverters connected in parallel and having a primary electronic control unit - Google Patents

Abstract

A solar inverter (1) comprises a plurality of individual inverters (11-13) that are connected in parallel, each having a power unit (6) for converting a field voltage (UF) on the input side into a mains voltage (UN) on the output side and a primary electronic control unit (7). According to the invention, the control unit (7) is designed to carry out all primary control functions and the control functions that can be associated with the individual inverters (11-13).

Description

description

Solar inverter with several parallel single inverters and with a superordinate electronic control unit

The invention relates to a solar inverter with a plurality of parallel-connected individual inverters, each having a power section for converting an input-side field voltage into an output-side mains voltage and with a higher-level electronic control unit.

The considered solar inverters convert the DC voltage provided by a solar field or one or more solar modules into an AC voltage. The solar inverter can, for example, feed the output side into a single-phase 50 Hz / 230 V power supply network or into a 60 Hz / 120 V power supply network of an energy supply company. For large solar fields preferably three-phase inverters are used, which in a corresponding three-phase power supply network such. B. in a 50Hz / 400V power grid, feed. It is also possible to connect several solar inverters to a common busbar, into which the solar field or the solar modules feed.

Solar inverters, which are connected on the input side to a solar field, usually have several parallel-connected individual inverters, which are switched on individually as the intensity of the solar radiation increases. When all single inverters are connected, a maximum electrical power can be fed back into the power supply network. The gradual connection improves the efficiency of the entire solar inverter or the entire photovoltaic system with smaller irradiation values.

In addition to a power unit, each individual inverter has its own control electronics unit, in which the judge functions, such. As the control of power semiconductors, current and voltage control, protection and monitoring, can be realized for each inverter. A higher-level controller, in particular an electronic control unit, takes over the coordination of the entire solar inverter and, among other things, switches the individual inverters on and off depending on the operating state of the system. The electronic control unit also provides the setpoint values for the individual inverters, in particular a mains voltage or a mains current. The required control and control functions of the solar inverter are processed distributed on different electronic modules. The respective individual inverters are interconnected for data exchange. The control electronics units of the individual inverters are usually connected via a communication bus with the higher-level control unit. This bus connection can be for example a parallel or a serial bus. Alternatively or additionally, the data or signal exchange between the respective individual inverters and the superordinate electronic control unit can take place via digital or analog signal lines.

A disadvantage of the solar inverters described above is the complex programming of the plurality of control electronics units and the superordinate electronic control unit. This requires the use of various programming tools, which are each tailored to the higher-level control unit and to the control electronics units of the individual inverters. Another disadvantage is the complex data storage and archiving of the source and object files as well as the associated change management of the developed software. Another disadvantage is the time-consuming troubleshooting, if one of the control electronics units of the individual inverter should be faulty.

It is therefore an object of the invention to provide a modular solar inverter with several individual alternating indicate which no longer has the aforementioned disadvantages.

The object of the invention is achieved with a solar inverter with the features of claim 1. Advantageous embodiments of the solar inverter are mentioned in the dependent claims 2 to 7.

According to the invention, the electronic control unit is designed to carry out all higher-level control and control functions that can be assigned to the respective individual inverters.

This has the great advantage that, instead of a large number of electronic control units in the individual inverters and the superordinate electronic control unit, only one (single) central control unit is used, which takes over all the control and control functions of the solar inverter constructed from several individual inverters , In other words, no regulation takes place in the respective individual inverters. This has the further advantage that the individual inverters no longer have to be configurable and can therefore be designed as a "black box".

The structure of the solar inverter according to the invention also leads advantageously to a simplified installation and to a lower total power consumption due to the presence of only a single central control unit. Another advantage is the higher reliability, since only a single electronic control unit is available. This advantageously reduces the hardware costs as well as the development and configuration costs for the entire solar inverter. In addition, the commissioning of the solar inverter according to the invention and the time required for troubleshooting in the solar inverter are simplified due to the greatly reduced number of possible sources of error. According to one embodiment, the electronic control unit and all individual inverters are connected to each other via a communication bus. The communication bus may be, for example, a serial or a parallel communication bus. He can z. B. a CAN bus, a fieldbus or a so-called "DRIVE-CLiQ" be.

According to one embodiment of the invention, the electronic control unit has first means for mains current control and superimposed mains voltage control for each individual inverter. The individual inverters each have an ammeter and a voltmeter for detecting a mains actual value and a mains voltage actual value. The individual inverters each have a signal conditioning unit for signal conditioning and forwarding of the detected actual values to the control unit. The individual inverters each have the signal conditioning unit for converting a respective mains current setpoint supplied by the control unit and a respective mains voltage setpoint into a corresponding pulse sequence for controlling switching elements of the respective power section.

The signal conditioning unit of each individual inverter serves (exclusively) to convert the respective current setpoint or voltage setpoint into the respective corresponding pulse sequence for controlling the power semiconductors without any feedback effect. Preferably, the signal processing unit forms the respective setpoint value, transmitted in the form of data words, according to one in one

Program memory of the signal processing unit deposited algorithm into corresponding binary signal sequences. Alternatively, the transmitted data words may address a read-only memory in the signal processing unit, which then provides a plurality of corresponding binary pulse values. The latter preferably form an on / off ratio of the respective switching element to be controlled, which corresponds to the respective desired value. The binary impulse values are cyclically repeated as binary signal sequences for generating the output-side single- or multi-phase mains voltage. The binary signal sequences can be raised by means of a downstream driver or amplifier to a required voltage level for driving the preferably semiconductor-based switching elements.

In the opposite direction, the signal conditioning unit serves to digitize the detected analog current and voltage actual values and to output these in the form of data words via the communication bus to the central control and regulation unit. For digitization is preferably an analog / digital converter.

According to an alternative embodiment, the electronic control unit has second means for mains current control and superimposed mains voltage control and for phase current control and phase voltage control of the individual inverters for each individual inverter. The solar inverters each have an ammeter and a voltmeter for detecting a mains actual value and a mains voltage actual value, and at least one phase current meter and at least one phase voltage meter for detecting respective phase current actual values and respective phase voltage actual values. The individual inverters each have a signal processing unit for signal processing and forwarding of the detected actual values to the control unit. The second means of the electronic control unit then convert the processed actual values in a control loop into a corresponding pulse sequence for controlling switching elements of the respective power unit.

In comparison with the previous embodiment, the function of the signal conditioning unit is limited to the fact that the digitally coded drive pulses, which are preferably transmitted via the communication bus, are converted directly into binary drive pulses for the respective switching elements. In the simplest case, two data bits will be consecutive Inverter phase transmitted, which correspond to the binary switching states of the respective phase associated switching elements.

The digitization of all voltage and current values recorded by the current and voltage meters takes place the other way round. The corresponding digitally coded actual values are output as data words to the communication bus.

For the alternative case in which the current and voltage meters already provide the detected current and voltage actual values digitally, the signal conditioning unit is provided for outputting the already digitized actual values to the communication bus according to a defined bus protocol.

In particular, the electronic control unit has a multitasking and / or real-time operating system. This ensures that a large number of parallel single inverters can be reliably controlled. The operating system is preferably designed so that a large number of modular individual inverters can be integrated and operated automatically in the installation slots provided for this purpose in the solar inverter in terms of control and regulation.

According to a further embodiment, the individual inverters each have an input-side switching means for switching the respective individual inverters to the field voltage and / or in each case an output-side switching means for

Switch the respective individual inverters to the mains voltage. The electronic control unit is connected to the switching means for individually controlling the switching means. This has the advantage that, depending on the radiation intensity, a corresponding number of individual inverters can be switched on or off. This increases the overall efficiency of such a solar change richter. Preferably, the switching means is a relay or a contactor.

In particular, the individual inverters each have a three-phase power unit for converting the input-side field voltage into an output-side three-phase mains voltage. In a corresponding manner, the signal conditioning units are designed for the three-phase case.

The invention and advantageous embodiments of the invention will be described in more detail below with reference to the following figures. Show it:

1 shows a basic structure of a solar inverter with, for example, three individual inverters, each with a control electronics unit and with a higher-level control unit,

2 shows by way of example a solar inverter according to the invention with three individual inverters and with a higher-level central control unit,

3 shows by way of example a basic circuit diagram of a signal conditioning unit according to a first embodiment of the invention, FIG. 4 shows by way of example a basic circuit diagram of a signal conditioning unit according to a second embodiment of the invention and FIG

5 shows a block diagram of an exemplary single inverter with a signal conditioning unit and with a power unit according to the invention.

1 shows a solar inverter 1 with, by way of example, three parallel-connected individual inverters 11-13 each having a power section 6 for converting an input side

Field voltage UF in an output-side mains voltage UN and with a higher-level electronic control unit 70th The respective individual inverters 11-13 can be switched by means of input-side switching means 4 individually to DC voltage lines 21, which in turn are connected to a solar panel 2 or with one or more solar modules. UF denotes a field voltage or DC link voltage that is related to a first reference potential 22. Furthermore, the respective individual inverters 11-13 can be individually connected to a power supply network 3 by means of output-side switching means 5. The switching means 4, 5 shown are exemplary relays. With S1-S6 are

Control signals for driving the switching means 4, 5, which are output from the higher-level control unit 70. About the control signals S1-S6, the individual inverters 11-13 can be selectively switched on and off depending on the sun's rays.

In the present example, the feed is three-phase. It can alternatively be single-phase. The reference numeral 31 designates corresponding mains supply lines. With UN is a three-phase mains voltage referred to a second reference potential 32, such. B. ground potential, based. The electronic control unit 70 is connected, for example, via a communication bus 9 for exchanging data with the respective control electronics units 80 of the individual inverters 11-13. Via this communication bus 9, the electronic control unit 70 outputs a respective mains voltage setpoint UNS1-UNS3 or a respective mains current setpoint INS1-INS3 to the respective control electronics units 80 either for the higher-level voltage regulation or for the higher-level current regulation. With D1-D3 are more data, such as. As diagnostic data called. Among other things, they serve for monitoring or for determining the status of the individual inverters 11-13.

2 shows a block diagram of a solar inverter 1 according to the invention, which exemplifies three individual inverters 11-13 and a parent central Control and regulating unit 7 has as an electronic control unit.

The electronic control unit 7 has not further designated first means for superimposed mains current control or mains voltage control for each individual inverter 11-13. The electronic control unit 7 is connected to all individual inverters 11-13 via a communication bus 9. The data transmission can take place in parallel or in series. The control unit 7 outputs via this communication bus 9 a respective mains current setpoint INS1-INS3 or a respective mains voltage setpoint UNS1-UNS3 to a respective signal conditioning unit 8 of the individual inverters 11-13. In the opposite direction, the respective signal processing unit 8 outputs corresponding mains voltage actual values UNI1-UNI3 detected in the respective individual inverters 11-13 as well as mains actual values INI1-INI3 detected there to the communication bus 9 for control feedback to the electronic control unit 7.

For the higher-level control and regulation of the individual inverters 11-13, the electronic control unit 7 preferably has a multitasking and / or real-time operating system. As a result, a reliable operation and a simple extension of the solar inverter 1 according to the invention by further individual inverters 11-13 are possible.

3 shows a block diagram of an exemplary signal conditioning unit 8 according to a first embodiment of the invention.

The signal conditioning unit 8 shown serves to convert a respective mains current setpoint INS supplied by the control unit 7 via the communication bus 9 or a respective mains voltage setpoint value USS into a corresponding one

Pulse train P1-P6 for controlling switching elements of the respective power section. In the example of FIG 3, the Implementation three-phase, with a separate pulse generator 83 is present for each phase of the network.

In the example of FIG. 3, the processing of the respective mains current setpoint INS or mains voltage setpoint UNS is combined in a subunit 81 of the signal conditioning unit 8. In the lower part of FIG. 3, a second subunit 82 of the signal conditioning unit 8 is shown. It is used to signal processing and forwarding of the detected actual values INI, UNI to the control unit 7. The output is in turn sent to the communication bus 9. In particular, the signal conditioning unit has an analog / digital converter 84, which usually the analog input actual values INI, UNI digitized and outputs these as digitally coded values INI ', UNI' to the communication bus 9.

In addition, in particular for protection purposes, as shown in the example of FIG. 3, respective detected field voltage actual values UFI and / or field current actual values IFI can be converted by means of the analog / digital converter 84 into corresponding digitally coded values UFI ', IFI'.

4 shows a block diagram of a signal conditioning unit 8 according to a second embodiment of the invention.

In the example of FIG. 4, the signal conditioning unit 8 has a further pulse generator 85, which transmits the digitally coded control signals P1 '-P6' transmitted by the central control and regulation unit 7 via the communication bus 9 into corresponding control signals P1-P6 for, in particular, direct control of the switching elements of the power unit. So z. B. the illustrated six digitally coded control signals Pl '-P6' are transmitted as a data word via the communication bus 9, wherein one bit of this data word represents the corresponding switching state of a switching element. For example, a logical "1" of the corresponding bit may represent a positive drive signal for the switching element to be driven, while a logical "1" may represent a positive drive signal for the switching element to be driven "0" of this data word represents a blocking signal for the switching means to be controlled.

In the lower part of FIG. 4, in turn, a second subunit 82 of the signal conditioning unit 8 is shown for transmitting the actual values UFI, IFI, IRI, ITI, USTI, URSI. Reference numeral 84 designates an analog / digital converter, which in addition to a field voltage actual value UFI and a field current actual value IFI additionally digitizes two actual phase current values IRI, ITI and two phase voltage actual values USTI, URSI. The signal processing unit 8 converts these into "bus-capable" digitally coded actual values UFI ', IFI', IRI ', ITI', USTI ', URSI' for forwarding to the communication bus 9. In the example of FIG. 4, only two phase current values IRI, ITI and two phase voltage actual values USTI, URSI digitized The remaining third phase quantities can be calculated from the first two.

In the example of FIG 5, a schematic diagram of a single inverter 11-13 is shown according to the invention. In the upper part of FIG. 5, the signal conditioning unit 8, in the lower part of FIG. 5, the circuit diagram of the associated power unit 6 is shown. The power unit 6 has in the left part of FIG. 5 a voltage intermediate circuit designated by the reference numeral 60. At this voltage intermediate circuit 60, the field voltage UF is applied. The field voltage UF can consequently also be referred to as intermediate circuit voltage. Reference symbol IF denotes the associated field current flowing into the intermediate circuit 60. The intermediate circuit 60 has an intermediate circuit capacitor 69 for buffering the input voltage UF. For measuring the intermediate circuit voltage or the field voltage UF, a voltmeter 91 is present. This outputs a corresponding field voltage actual value UFI to the signal conditioning unit 8. Furthermore, an ammeter 92 is present in the intermediate circuit 60, which serves for measuring the field current IF and outputs a corresponding actual value IFI to the signal conditioning unit 8. In the lower right part of FIG 5, a three-phase inverter unit 68 is shown. It sets by appropriate control of their respective switching elements 61-66 which there applied intermediate circuit voltage UF in a three-phase mains voltage UN. In the example of FIG. 5, the switching elements 61-66 are semiconductor switches. The semiconductor switches 61-66 shown are so-called IGBT transistors (IGBT = Insulated Gate Bipolar Transistor). Antiparallel to the respective transistors 61-66, a freewheeling diode 67 is connected. For measuring the output-side phase currents IPR, IPS, IPT two phase current meters 93, 94 are present. The missing phase current IPS can be derived from the two already detected phase currents IPR, IPT. The corresponding phase current actual values IRI, ITI are supplied to the associated signal conditioning unit 8. to

Phase voltage measurement are two phase voltage meters 95, 96 available. The remaining phase voltage can also be derived from the already detected phase voltages. The corresponding phase voltage actual values USTI, URSI are supplied to the signal conditioning unit 8.

The signal conditioning unit 8 also has a bus interface 86, which converts the data traffic from and to the communication bus 9 into corresponding binary data for further processing in the signal conditioning unit 8. By the reference numeral 87 is exemplified a multiplexer, which converts the coming of a data word of the communication bus 9 binary information in parallel individual signals. The reference numeral 88 denotes amplifiers which convert the corresponding signals P1-P6 to the required voltage level for driving the semiconductor elements 61-66. In the lower part of the signal conditioning unit 8 again takes place the analog / digital conversion of the actual values UFI, IFI, IRI, ITI, USTI, URSI into corresponding data for transmission via the communication bus. 9

Claims

claims

1. Solar inverter with a plurality of parallel-connected individual inverters (11-13) each having a power section (6) for converting an input-side field voltage (UF) in an output side grid voltage (UN) and with a higher-level electronic control unit (7), characterized in that the Control unit (7) is designed to carry out all higher-level control and control functions that can be assigned to the respective individual inverters (11-13).

2. Solar inverter according to claim 1, characterized in that - the electronic control unit (7) has first means for superimposed mains current regulation or mains voltage regulation for each individual inverter (11-13),

- That the individual inverters (11-13) each have a current meter (92) and a voltmeter (91) for detecting a net current value (INI) and a mains voltage actual value (UNI) and

- That the individual inverters (11-13) each have a signal conditioning unit (8) for signal conditioning and forwarding of the detected actual values (INI, UNI) to the control unit (7) and for implementing a respective from the control unit (7) supplied mains current setpoint (INS ) or a respective mains voltage setpoint (US) into a corresponding pulse sequence for controlling switching elements (61-66) of the respective power section (6).

3. Solar inverter according to claim 1, characterized in that

- That the electronic control unit (7) second means for superimposed mains current control or mains voltage control and for phase current control and phase voltage control of the individual inverters (11-13) for each individual inverter (11-13), - That the solar inverters (11-13) each have a current meter (92) and a voltmeter (91) for detecting a Feldstromistwertes (IFI) and a Feldspannungsistwertes (UFI) and at least one phase current meter (93, 94) and at least one phase voltage meter (95, 96) for detecting respective phase current actual values (IRI, ITI) and respective phase voltage actual values (USTI, URSI),

- That the individual inverters (11-13) each have a signal conditioning unit (8) for signal conditioning and forwarding of the detected actual values (IFI, UFI, IRI, ITI, USTI, URSI) to the control unit (7) and

- That the second means of the electronic control unit

(7) convert the processed actual values (IFI, UFI, IRI, ITI, USTI, URSI) into a corresponding pulse train for the control of switching elements (61-66) of the respective power section (6).

4. solar inverter according to one of the preceding claims, characterized in that the electronic control unit (7) and all individual inverters (11-13) via a communication bus (9) are interconnected.

5. Solar inverter according to one of the preceding claims, characterized in that the electronic control unit (7) has a multitasking and / or real-time operating system.

6. Solar inverter according to one of the preceding claims, characterized

in that the individual inverters (11-13) each have an input-side switching means (4) for switching the respective individual inverters (11-13) to the field voltage (UF) and / or an output-side switching means (5) for switching the respective individual inverters ( 11-13) to the mains voltage (UN) and - That the electronic control unit (7) for individually controlling the switching means (4, 5) with the switching means (4, 5) is connected.

7. Solar inverter according to one of the preceding claims, characterized in that the individual inverters (11-13) each have a single-phase or three-phase power unit (6) for converting the input-side field voltage (UF) into an output-side single-phase or three-phase mains voltage (UN ) exhibit.