EP3729591A1

EP3729591A1 - Feeding electric power from a photovoltaic system into an ac system having a low short-circuit capacity

Info

Publication number: EP3729591A1
Application number: EP18799528.7A
Authority: EP
Inventors: Daniel PREMM; Vitali Sakschewski
Original assignee: SMA Solar Technology AG
Current assignee: SMA Solar Technology AG
Priority date: 2017-11-16
Filing date: 2018-11-06
Publication date: 2020-10-28
Also published as: US11557899B2; WO2019096631A1; AU2018366935A1; US20200274459A1; AU2018366935B2

Abstract

In order to feed, via a system terminal point (2), electric power from a photovoltaic system (1), which includes at least one first inverter (5) that operates as a current source and is connected to a photovoltaic generator (8) at the DC end and to the system terminal point (2) at the AC end, into an AC system (3) having a low short-circuit capacity, a second inverter (6) of the photovoltaic system (1) is connected to the system terminal point (2) and operates as a voltage source.

Description

INJECTION OF ELECTRICAL PERFORMANCE OF A PHOTOVOLTAIC SYSTEM INTO A LOW SHORT POWER AC POWER

TECHNICAL FIELD OF THE INVENTION

The invention relates to a method for feeding electrical power of a photovoltaic system via a grid connection point in an AC network. More particularly, the present invention relates to a method having the features of the preamble of independent claim 1. Furthermore, the present invention relates to a photovoltaic system for carrying out such a method. In particular, the present invention relates to a photovoltaic system having the features of the preamble of independent patent claim 6.

STATE OF THE ART

In the decentralized feeding of regeneratively generated electrical power into AC grids, it is known that problems arise due to high network impedances, which are unavoidable in the case of long connecting lines. The result of the high network impedances is that the supplied electrical power leads to a significant increase in the AC voltage applied to the grid connection point. In addition, fluctuations in the supplied electrical power lead to fluctuations in the AC voltage applied to the grid connection point. As a result, it is difficult to stably drive inverters that are used to supply the electric power and that continuously synchronize with the AC voltage. Practically emergency shutdowns occur, although the AC mains would basically be able to absorb the available, regeneratively generated electrical power.

In a wind turbine it is known to use so-called STATCOMs and capacitor banks as well as synchronous capacitors to stabilize the AC voltage at a grid connection point. These are comparatively complex measures.

WO 2013/041534 A2 discloses a method for controlling a photovoltaic system connected to an alternating current network with a photovoltaic generator and an inverter. It is done with the inverter depending on a received power control signal transfers electrical power between the photovoltaic generator and the AC network, which includes positive and negative dynamic control power. The photovoltaic generator is connected via a DC / DC converter to an input side DC voltage intermediate circuit of the inverter, to which furthermore a battery is connected via a bidirectional DC / DC converter. With the help of the battery, the inverter can provide positive control power for the AC grid independent of the supply of electrical power from the photovoltaic generator. The battery is charged with electrical power from the photovoltaic generator or the AC mains and kept charged until positive control power is needed. Then, the cached in the battery electric power via the battery inverter and the inverter is fed into the AC mains.

From DE 101 40 783 A1 a device for equal parallel operation of at least two inductively coupled inverters without additional synchronization and / or communication device is known. Each inverter is provided with a control circuit intended for regulating its output voltage, to which a reference voltage is supplied as reference voltage whose frequency, taking into account a preselected frequency statics, is derived from the reactive power and its amplitude taking into account a preselected voltage statics from the reactive power. Active power oscillations between the inverters are avoided by phase precontrol.

OBJECT OF THE INVENTION

The problem is the feeding of comparatively large electrical power of a photovoltaic system via a grid connection point in an AC network comparatively small short-circuit power, especially if the short-circuit power of the AC network at the grid connection point is not more than twice as large as the total short-circuit power of all inverters, with which the electrical power the photovoltaic system is fed to the grid connection point. Difficulties can occur even if this ratio is less than 3. The invention is therefore based on the object to show a method for feeding electrical power of a photovoltaic system via a grid connection point in an AC network and a corresponding photovoltaic system, which work stably even at low short-circuit power of the AC network. SOLUTION

The object of the invention is achieved by a method having the features of independent patent claim 1 and a photovoltaic system with the features of independent patent claim 6. Preferred embodiments of the method according to the invention are defined in dependent claims 1 to 5 and preferred embodiments of the inventive photovoltaic system in the dependent claims 6 to 11.

DESCRIPTION OF THE INVENTION

In the method according to the invention for feeding electrical power of a photovoltaic system via a grid connection point in an AC network low short circuit power, wherein at least one DC side of a photovoltaic generator and the AC side connected to the power supply first inverter of the photovoltaic system is operated in a conventional manner as a power source, a to the network connection point connected second inverter of the photovoltaic system operated as a voltage source.

The fact that the second inverter of the photovoltaic system connected to the mains connection is operated as a voltage source here means that it is operated as a so-called network generator. Thereby, the AC voltage registered by all the first inverters at their AC side terminals is defined together by the external AC low short-circuit power network and the second inverter. The first inverters are therefore not affected in their operation by the weakness of the AC network low short-circuit power. Rather, they can be operated as if they were connected to a high-short-circuit AC power supply whose AC voltage can not shift the first inverters by the electrical power they feed to disrupt themselves or other first inverters in their operation.

Specifically, the second inverter of the photovoltaic system can be operated as a voltage source on the basis of measured values of an alternating voltage measured in the area of the photovoltaic system and of predetermined characteristic curves, which are also referred to as so-called voltage statistics. The measured alternating voltage may in particular be the alternating voltage at the alternating-voltage side terminals of the second inverter. In other words, the second inverter can be self-sufficient all first inverters are operated, whereby no coordinated operation of multiple first inverter is necessary. The control of an inverter operated as a voltage source or network generator on the basis of measured values of an alternating voltage and given characteristic curves or voltage statistics is basically known, for example to form an alternating current network with several inverters connected in parallel.

In the method according to the invention, both active and reactive power can be fed in at the network connection point with the second inverter. It is understood that the second inverter must be designed for feeding also reactive power in a suitable manner. The person skilled in the art, however, corresponding inverter designs are known. The second inverter is also regularly bidirectional form to fully fulfill its function as the voltage applied to the first inverters AC stabilizing network generator by if necessary also outputs negative power to the grid connection point, d. H. positive performance from there. By contrast, all first inverters of the photovoltaic system according to the invention are typically unidirectional inverters.

The inventive method can be carried out so that a single second inverter of the photovoltaic system is operated as a voltage source or network generator, while a plurality of parallel-connected first inverters is operated in a conventional manner as a power source. That is, for the stabilization of the AC voltage applied to the first inverters with which they synchronize, a single second inverter is usually sufficient. With higher stabilization requirements, however, several second inverters can also be used. In practice, second inverters can be connected to the connection point as long as the AC voltage applied to the first inverters is sufficiently stabilized.

As a criterion for sufficient stabilization of the AC voltage applied to the first inverters may apply that a total short-circuit power, which includes the short-circuit performance of the AC mains at the grid connection point and all network-forming second inverter is at least twice as large as a total short-circuit power of all first inverters. Preferably, the ratio is at least 2.5: 1, more preferably at least 3: 1. In this case, the respective short-circuit power is to be understood as the power which results as the product of the maximum short-circuit current from the AC mains or the respective inverter and the AC voltage at the mains connection. In a photovoltaic system according to the invention for carrying out the method according to the invention for feeding electrical power of the photovoltaic system via a network connection point in an AC network low short-circuit power is at least one DC voltage side to a photovoltaic generator and AC voltage side connected to the mains connection first inverter of the photovoltaic system as a power source and connected to the network connection point second Inverters of the photovoltaic system designed as a voltage source or network generator. In this case, the design as a current source or voltage source implies that the second inverter is in principle suitable from its electrical circuit as a current source or voltage source and that it is actually operated in the intended operation of the photovoltaic system according to the invention.

In the case of the photovoltaic system according to the invention, the first inverters are connected to the respective photovoltaic generator via a respective first DC voltage intermediate circuit with a first DC link capacitance on the DC voltage side. The second inverter is connected to a second DC voltage intermediate circuit with a second DC link capacity. The second intermediate circuit capacitance is increased by at least 100%, preferably by at least a factor of 3 or by at least a factor of 5 compared to the first intermediate circuit capacitance in order to provide the second inverter with the power to be fed by it to stabilize the AC network at the grid connection point in the shortest possible time to ensure that it raises the short-circuit power of the AC network at the grid connection point to the desired level.

In the case of the photovoltaic system according to the invention, a photovoltaic generator can also be connected to the second DC voltage intermediate circuit on the input side of the second inverter, so that the second inverter also feeds electrical power from one of the photovoltaic generators of the photovoltaic system into the AC grid at the grid connection point. Even then, the second DC link capacity is increased by at least 100% compared to each first DC link capacity.

To increase the second DC link capacity may, alternatively or in addition to a correspondingly large-sized capacitor z. B. a supercapacitor and / or a lithium-ion battery to be connected to the second intermediate circuit, which serves beyond the capacity increase addition as electrochemical energy storage. Even if another photovoltaic generator is connected, the second DC intermediate circuit can be charged on the input side of the second inverter via the bidirectionally formed second inverter.

The photovoltaic system according to the invention is typically intended to feed electrical power into a three-phase AC grid. Accordingly, the second inverter is then preferably a three-phase inverter.

As already indicated for the method according to the invention, many more first inverters can be present as second inverters. In particular, even if the second inverter or inverters are provided for feeding electrical power from photovoltaic generators into the AC grid at the grid connection point, their number can be increased by corresponding modification or conversion from first to second inverters until the voltage applied to the grid connection point AC power is sufficiently stabilized, for example, by the total short-circuit power of the external AC mains at the grid connection point and operated as a voltage source second inverter together at least two, two and a half or three times the total short-circuit power of all first inverters.

Advantageous developments of the invention will become apparent from the claims, the description and the drawings. The advantages of features and of combinations of several features mentioned in the description are merely exemplary and can take effect alternatively or cumulatively, without the advantages having to be achieved by embodiments according to the invention. Without thereby altering the subject matter of the appended claims, as regards the disclosure of the original application documents and the patent, further features can be found in the drawings, in particular the illustrated geometries and the relative dimensions of several components and their relative arrangement and operative connection. The combination of features of different embodiments of the invention or of features of different claims is also possible deviating from the chosen relationships of the claims and is hereby stimulated. This also applies to those features which are shown in separate drawings or are mentioned in their description. These features can also be combined with features of different claims. Likewise, in the Patent claims listed features omitted for further embodiments of the invention.

The features mentioned in the patent claims and the description are to be understood in terms of their number that exactly this number or a greater number than the said number is present, without requiring an explicit use of the adverb "at least". For example, when talking about an inverter, it should be understood that there is exactly one inverter, two inverters or more inverters. These features may be supplemented by other features or be the only characteristics that make up the product in question.

The reference numerals contained in the claims do not limit the scope of the objects protected by the claims. They are for the sole purpose of making the claims easier to understand.

BRIEF DESCRIPTION OF THE FIGURES

In the following the invention will be further explained and described with reference to preferred embodiments shown in the figures.

Fig. 1 illustrates a photovoltaic system according to the invention in a schematic

Einlinienschaubild.

FIG. 2 illustrates a first embodiment of a network generator

Inverter of the photovoltaic system according to FIG. 1.

Fig. 3 shows a second embodiment of the operated as a network generator

Inverter.

Fig. 4 shows a third embodiment of the operated as a network generator

Inverter; and

Fig. 5 shows a fourth embodiment of the operated as a network generator

Inverter of the photovoltaic system according to FIG. 1. DESCRIPTION OF THE FIGURES

The photovoltaic system 1 shown in Fig. 1 is used for feeding electrical power through a network connection point 2 in an external AC network 3, which has only a low short-circuit power at the network connection point 2, in particular due to a long connection line 4 and correspondingly high line impedances. Because of this low short-circuit power or the underlying line impedances, the electrical power fed in by the photovoltaic system 1 at the grid connection point 2 influences the AC voltage of the AC grid 3 present at the grid connection point 2 quite considerably. The AC voltage at the grid connection point 2 can thus far as compared to the rated voltage of the

AC network 3 are moved that a stable operation of the photovoltaic system 1 is no longer possible. In particular, there is the danger that the first inverters 5 of the photovoltaic system 1, which are operated as current sources and synchronize to the AC voltage at their AC-side terminals, are switched off because the increase in the AC voltage at their AC-side terminals caused by them exceeds a voltage range, in which a stable operation of the first inverter 5 is possible. To compensate, the photovoltaic system 1 has a second inverter 6, which is operated as a voltage source, specifically as a network generator for the voltage applied to the first inverters 5 local AC network. Specifically, the operation of the second inverter 6 is parallel to the external AC network with respect to local AC network as in

Parallel operation of several network formers, for example in an island grid. The second inverter 6 thus stabilizes the alternating voltage applied to the first inverters 5, which thus can operate without interference despite the high line impedances of the connecting line 4 and fluctuating electrical power which is fed by the photovoltaic system 1. A photovoltaic generator 8 of the photovoltaic system 1 is connected in each case to input-side DC voltage intermediate circuits 7 of the first inverters 5, so that each of the first inverters 5 feeds electrical power from one of the photovoltaic generators 8 to the grid connection point 2. To an input side DC voltage intermediate circuit 9 of the second inverter 6, an energy storage device 10 is connected. This energy store 10 is designed such that it can briefly provide the second inverter 6 with a high electrical power in order to feed it to the grid connection point 2 in order to stabilize the AC voltage. It involves the injection of both active power and reactive power and both positive power and negative power. Accordingly, the second inverter 6 formed in contrast to the unidirectionally formed first inverters 5 bidirectional.

In FIG. 1, the first inverters 5 and the second inverter 6 are shown connected directly to the grid connection point 2. However, especially with large photovoltaic systems, at least one transformer stage will regularly be connected between the entirety of the inverters 5, 6 and the grid connection point. It is also possible to connect a plurality of transformer stages in parallel between in each case one or more of the inverters 5, 6 and the grid connection point 2. This does not change the basic mode of operation and function of the second inverter 6.

FIG. 2 shows an embodiment of the first inverter 6 according to FIG. 1 and of the energy store 10 connected thereto. Concretely, the energy store 10 here is a capacitor 11 which provides the DC intermediate circuit 9 with a high DC link capacitance. In particular, the DC link capacitance of the DC intermediate circuit 9 is at least twice as large as the DC link capacitance of each of the input DC voltage intermediate circuits 7 of the first inverters 5.

In the embodiment of the second inverter 6 and the input side DC voltage intermediate circuit 9 shown in FIG. 3, the energy storage 10 is a lithium-ion battery 12, which is connected directly to the DC voltage intermediate circuit 9 and thus increases its DC link capacity. The lithium-ion battery 12 is suitable for a variety of charging and discharging cycles. Instead of the lithium-ion battery, an electrochemical capacitor, i. H. a so-called supercapacitor, find use, which has a higher power density than the lithium-ion battery 12, however, which is characterized by a higher energy density.

In the embodiment of the second inverter 6 according to FIG. 4 or its input-side DC intermediate circuit 9, a further photovoltaic generator 13 is connected in addition to the large-sized capacitor 1 1 or a corresponding capacitor bank. Accordingly, with the second inverter 6 according to FIG. 4, electrical power is also supplied by the photovoltaic generator 13 at the grid connection point 2 according to FIG. 1. However, the second inverter 6 still differs from the first inverters 5 according to FIG. 1 in that it is not operated as a power source but as a voltage source and network generator and that the DC link capacitance of its DC intermediate circuit 9 is significantly higher than the DC link capacitance of the DC voltage intermediate circuits 7 of the first inverter. 5

In the embodiment of the second inverter 6 and its input-side DC voltage intermediate circuit 9 according to FIG. 5, a lithium-ion battery 12 is connected in addition to the embodiment according to FIG. 4 via a battery converter 14 in the form of a bidirectional DC / DC converter 15. Thus, the energy storage device 10 is formed here by the capacitor 1 1 and the battery 12.

LIST OF REFERENCE NUMBERS

photovoltaic system

Grid connection point

AC power

connecting cable

first inverter

second inverter

(first) DC voltage intermediate circuit

photovoltaic generator

(second) DC voltage intermediate circuit

energy storage

capacitor

Lithium Ion Battery

(further) photovoltaic generator

battery converter

bidirectional DC / DC converter

Claims

1. A method for feeding electrical power of a photovoltaic system (1) via a network connection point (2) in an AC network (3) low short-circuit power,

wherein at least one DC voltage side to a photovoltaic generator (8) and the AC side to the grid connection point (2) connected to the first inverter (5) of the photovoltaic system (1) is operated as a power source, and

a second inverter (6) of the photovoltaic system (1) connected to the grid connection point (2) is operated as a voltage source

characterized,

the second inverter (6) of the photovoltaic system (1) is operated on the basis of measured values of an alternating voltage measured in the region of the photovoltaic system and a predetermined characteristic as a voltage source,

wherein a first total short-circuit power 1.GKL of all the first inverter (5) operated as a current source and a second total short-circuit power 2.GKL of the AC network (3) and of all second inverters (6) operated as a voltage source is

2.GKL / 1.GKL is greater than or equal to 2.

2. The method according to claim 1, characterized in that with the second inverter (6) active and reactive power to the network connection point (2) is fed.

3. The method according to claim 1 or 2, characterized in that a single second inverter (6) of the photovoltaic system (1) is operated as a voltage source.

4. photovoltaic system (1) for carrying out the method for feeding electrical power of the photovoltaic system (1) via a network connection point (2) in an AC network (3) low short-circuit power according to one of the preceding claims,

wherein at least one DC side of a photovoltaic generator (8) and the AC side to the grid connection point (2) connected first inverter (5) of the photovoltaic system (1) is designed as a power source and connected to the network connection point (2) second inverter (6) of the photovoltaic system ( 1) is designed as a voltage source

characterized, in that the at least one first inverter (5) is connected to the photovoltaic generator (1) via a first DC voltage intermediate circuit (7) with a first intermediate circuit capacitance and the second inverter (6) is connected to a second DC voltage intermediate circuit (9) on the DC side with respect to the first DC link capacitance is increased by at least 100% increased second DC link capacity.

5. photovoltaic system (1) according to claim 4, characterized in that the second inverter (6) is a bidirectional inverter.

6. Photovoltaic system (1) according to claim 4, characterized in that a lithium-ion battery (12) and / or a supercapacitor is connected to the second DC voltage intermediate circuit (9).

7. photovoltaic system (1) according to claim 4, characterized in that the second DC voltage intermediate circuit (9), a further photovoltaic generator (13) is connected.

8. photovoltaic system (1) according to one of claims 6 to 7, characterized in that the AC mains (3) is three-phase and that the second inverter (6) is a three-phase inverter.