DE102010023113A1 - System for dynamic regulation of regenerative energy generation installation with multiple energy generation units, has signal input for receiving pre-determined nominal value - Google Patents

Abstract

The system has a signal input for receiving a pre-determined nominal value and a measuring device for measuring an actual value on an output of an energy generation installation. A regulating device is provided for regulating energy generation units based on the nominal value and the measured actual value. An independent claim is also included for a method for dynamic regulation of a regenerative energy generation installation with multiple energy generation units.

Description

The invention includes power plant monitoring and control concepts that take into account the evolution of the requirements for the operation of photovoltaic power generation plants.

The expansion of renewable energies is leading to new requirements for the availability and operational safety of energy grids, because fluctuating and difficult-to-predict generation supply now comes with fluctuations over time.

In order to ensure a high availability and stable supply network also for the future, were with the EEG amendment (October 2008) and the Medium Voltage Directive of the BDEW (January 2009) The legislator and network of energy network operators have created the legal and technical basis for integrating renewable energy generation plants with more than 100 kWp into existing supply networks as controllable power plants.

This creates new requirements for the planning, system technology and operation of PV power plants. In particular, reliable process control technology and intelligent power plant management play a major role in the efficient and cost-effective implementation.

So far, network operators have not been able to set uniform, detailed requirements for network safety management, power plant control, protection functions, and the process control interfaces used. This currently results in very different requirements depending on the voltage level of the network connection point and the responsible network operator. A consultation with the responsible network operator on the requirements for participation in network security management is therefore recommended in parallel with the application for a connection.

In principle, participation in network security management is mandatory for installations above 100 kW nominal power. In this case, by specifying a power level, the grid operator can limit the active power feed of the PV power plant to a specific percentage of the power plant nominal power (currently 100%, 60%, 30%, 0%). This is done by a predetermined by the network operator Prozessleitschnittstelle to which the power plant control is connected. If necessary, the successful implementation of this specification must be communicated to the network operator by means of the process control interface.

So far, in the prior art, the power reduction is performed as pure control. This means that an actuating command coming from the energy supplier is sent directly to all inverters in the power plant and all are throttled down to the same percentage. As a result of losses in the internal power transmission of the power plant as well as possible unavailability of inverters (for example, disconnected units in the repair), this leads to yield losses in excess of the required throttling.

The object of the invention was accordingly to provide a system which does not have the disadvantages of the prior art.

This object is achieved with the features of claims 1, 8 and 11, respectively. Advantageous embodiments of the invention are defined in the dependent claims.

The invention extends the range of PV system technology from comprehensive, manufacturer-independent monitoring of large PV power plants to complete control room functionality with intelligent power plant control concepts.

The concepts support and improve the power plants with a monitoring. Central is the power reduction on request of the energy supplier. A regulation by measuring the actual output power of the power plant as well as comparison with the specification and a corresponding tracking of the inverter control in a closed control chain can avoid these yield losses.

This closed-loop approach can be further improved by using the data obtained from monitoring. For this purpose, the current availability and utilization of all plant components is included in the calculation of the control and thus the power to be reduced is distributed to individual inverters. On the one hand, this helps to carry out the regulation from each state of the power station as quickly and efficiently as possible. On the other hand, inverters of different rated power and even different manufacturers can be integrated into the power management in a power plant and the load (or reduction through the reduction) can be distributed dynamically.

Also on the regulation of electrical parameters at the network connection point (such as the displacement factor cos-phi, the mains frequency or the mains voltage), this concept can be extended. In particular, the compensation of reactive power would benefit from a differentiated control system designed for each inverter Real power yield and the load distribution in the power plant result.

• – Stabilisierung des Verschiebungsfaktor (cos φ) auf einen festen, vorgegebenen Wert am Netzverknüpfungspunkt
• – Stabilisierung des Verschiebungsfaktor (cos φ) auf einen variablen, vom Netzbetreiber über eine Prozessleitschnittstelle vorgegebenen Wert am Netzverknüpfungspunkt
• – Nachregelung des Verschiebungsfaktor (cos φ) in Abhängigkeit von der eingespeisten Wirkleistung oder bestehender Netzspannung nach einer vorgegeben Kurve mit einer vorgegeben Geschwindigkeit
• – Bereitstellung von Kurzschlussstrom (Fault Ride Through)
• – Wirkleistungsreduktion bis zur Abschaltung bei Über- und Unterfrequenz nach einem vorgegebenen Schema
• – Trennung der Erzeugungsanlage bei Unter- oder Überspannung nach einem vorgegebenen Spannungs-Zeit-Schema
• – Übermittlung der Ist-Werte an den Netzbetreiber über eine vorgegebene Prozessleitschnittstelle

Additional, potential requirements for individual PV power plants may consist of the following points, but are not exhaustive in this list:

• - Stabilization of the shift factor (cos φ) to a fixed, predetermined value at the network connection point
• Stabilization of the shift factor (cos φ) to a variable value specified by the network operator via a process control interface at the network connection point
• - Adjustment of the displacement factor (cos φ) as a function of the injected active power or existing mains voltage after a given curve with a predetermined speed
• - Provision of Fault Ride Through
• - Active power reduction to shutdown at overfrequency and underfrequency according to a predetermined scheme
• - Separation of the generating plant under under- or over-voltage according to a given voltage-time scheme
• - Transmission of the actual values to the network operator via a predetermined process control interface

• – Hard- und Software für die Prozessleittechnik mit Schnittstellen zu: – Messwandlern im Kraftwerk und am Netzverknüpfungspunkt – Funk-Rundsteuerempfänger und Prozessleitschnittstellen vom Netzbetreiber – Wechselrichter unterschiedlicher Hersteller
• – Wirkleistungsbegrenzung nach Vorgabe des Netzbetreibers auf eine vorgegebene Begrenzungsstufe innerhalb einer vorgegeben Zeit (Standard: eine Minute)
• – langsames, kontrolliertes Anfahren von gedrosselten Kraftwerken nach Aufhebung der Wirkleistungsbegrenzung durch den Netzbetreiber
• – Blindleistungsregelung am Netzverknüpfungspunkt auf einen vorgegeben, statischen oder variablen Verschiebungsfaktor (cos φ)
• – Blindleistungsregelung am Netzverknüpfungspunkt auf einen vorgegeben, von der Wirkleistung oder Netzspannung abhängigen Verschiebungsfaktor (cos φ)
• – Blindleistungskompensation von passiven Blindwiderständen in der Energieverteilung des Kraftwerkes (z. B. lange Erdkabeltrassen zu einem Übergabeumspannwerk) ab einem eingespeisten Wirkleistungsminimum
• – Netzfrequenzabhängige Wirkleistungsreduktion bei Abweichungen der Netzfrequenz zur Netzstützung
• – Überwachung aller Schaltvorgänge der kraftwerksweiten Schutzfunktionen (Abschaltung bei Über- oder Unterspannung)
• – teilweise Umsetzung von kraftwerksweiten Schutzfunktionen wie das Abschalten von weiterbestehenden Kurzschlüssen (soweit dies nicht durch jeden einzelnen Wechselrichter auf Niederspannungsseite garantiert ist)
• – Rückmeldung von Ist- und Sollwerten der Kraftwerksregelung an den Netzbetreiber über vielfältige Kommunikations- und Prozessleitschnittstellen
• – Rückmeldung einer Echtzeit-Ertragsprognose zur möglichen, momentanen Wirkleistungseinspeisung an den Netzbetreiber (zur Ermittlung des Ertragsausfalls bei Wirkleistungsbegrenzung)
• – Einbindung aller Mess- und Regelungswerte sowie aller Parameter der Kraftwerksregelung in das kontinuierliche, kraftwerksweite Monitoring zur: – Rückmeldung des Status der Kraftwerksregelung – Funktions- und Fehlerüberprüfung der Kraftwerksregelung – automatische Fehlerbenachrichtigung bei Abweichung von eingestellten Normen der Kraftwerksregelung – Archivierung aller Vorgabeereignisse vom Netzbetreiber sowie der entsprechenden Steuer- und Regelvorgänge im Monitoring zum späteren Nachweis von Reaktionszeiten und Ertragsausfällen

The invention can respond to the basic and specific requirements of network operators as a consequence of the Medium Voltage Directive and the EEG by providing:

• - Hardware and software for process control systems with interfaces to: - Instrument transformers in the power plant and at the grid connection point - Radio ripple control receiver and process control interfaces from the grid operator - Inverters from different manufacturers
• - Active power limitation as specified by the network operator to a specified limitation level within a specified time (default: one minute)
• - slow, controlled start-up of throttled power plants after termination of the active power limitation by the grid operator
• - Reactive power control at the grid connection point to a specified, static or variable displacement factor (cos φ)
• - Reactive power control at the network connection point to a specified displacement factor (cos φ) dependent on the active power or mains voltage
• - Reactive power compensation of passive reactances in the power distribution of the power plant (eg long underground cable routes to a transfer substation) from an injected active power minimum
• - Grid frequency-dependent active power reduction in case of deviations of the grid frequency for grid support
• - Monitoring of all switching operations of the power plant-wide protection functions (shutdown in case of overvoltage or undervoltage)
• - partial implementation of power plant-wide protection functions such as the switching off of existing short circuits (unless this is guaranteed by every single inverter on the low-voltage side)
• - Feedback of actual and setpoint values of the power plant control system to the grid operator via various communication and process control interfaces
• - Feedback of a real-time yield forecast for possible, instantaneous active power feed-in to the grid operator (to determine the yield loss during active power limitation)
• - Integration of all measurement and control values as well as all parameters of the power plant control in the continuous, power plant-wide monitoring for: - Feedback of the status of the power plant control - Function and error checking of the power plant control - Automatic error notification in case of deviation from set standards of power plant control - Archiving of all default events by the network operator and the corresponding control and monitoring processes in the monitoring for later detection of reaction times and yield losses

In the following the invention will be described in more detail with reference to the drawings, in which:

1 a block diagram of a system for monitoring a regenerative power generation plant.

2 a block diagram of a power plant control.

The drawings are merely illustrative of the invention and do not limit it. The drawings and the individual parts are not necessarily to scale. Like reference numerals designate like or similar parts.

1 schematically shows a block diagram of the system for dynamic monitoring. a regenerative power generation plant. The power generation plant may be, for example, a solar, wind or hydroelectric power plant. The power generation plant has several power generation units in the form of inverters. These inverters are regulated to control the power (P, Q) and / or electrical parameters (displacement factor, power factor, grid frequency and / or grid voltage) at the output or grid feed point of the power generation plant to certain specifications. In a first step, the system monitors the regenerative power generation plant and in a second stage the system controls the plant.

The specifications can be transmitted as individual values or as a common vector from the network control center to the power generation plant. The defaults or setpoints can be dynamic or static. For example, a fixed value or a dependence on the injected active power or on the mains voltage can be specified for the reactive power Q. A requirement for a fixed value or a specification for a specific reduction or increase within a certain time can be implemented by the regulation.

The default or the desired value is the control, for example, a PID controller supplied. As well as an actual value measured at an output or grid connection point of the power plant from a transducer or transducer. The controller controls several inverters, which can also be of different designs. For this purpose, one or more interface units may be provided to service the different protocols or signal levels of the inverters. The interface unit can be integrated in the controller or be an independent unit.

The control can receive measured values from the inverters, for example, to integrate their availability, load, and operating point into the control in order to minimize losses. Furthermore, the controller may consider passive power elements such as transformers, lines, etc. and the topology such as different line lengths or characteristics in the control to minimize losses.

This system controls the distributed system of power generation units so as to prevent or minimize losses due to de-energizing or inefficient use of the resources of the power plant.

2 shows a schematic representation of the power plant control, so to speak, the environment in which the system 1 is embedded. A control center of the network operator communicates with the power plant control to set values and obtain information and measurements on the state of the power plant. For this purpose, the power plant control has a control technology interface. The communication between the control system interface and the control system of the network operator via known wired or wireless communication channels.

The control technology interface is directly or indirectly connected to the controller functions of the power plant control. The controller functions correspond to the inner part of the control loop 1 , that is to say to the regulator and consideration of passive line elements according to 1 , The controller functions have one or more bidirectional interfaces to the inverters, as already in 1 discussed.

Furthermore, the controller functions have one or more bi-directional interfaces for power plant-wide monitoring in order to obtain information about the state of the entire power plant in the control and to take into account. On the other hand, the controller functions can output values and / or results from the control to the power plant-wide monitoring for use there.

The controller functions have one or more bi-directional interfaces to special measuring technology in order to be able to include further information in the control. The special measuring technology may include, for example, transducers that monitor the grid feed point. In addition, the special measuring technology can make all the measurement values, states or specifications that are important or desirable for the control available to the controller functions.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• EEG amendment (October 2008) [0003]
• BDEW (January 2009) [0003]

Claims (11)

A system for dynamically monitoring a regenerative power generation plant having a plurality of power generation units, comprising a signal input for receiving a target value (P _soll ), a measuring device for measuring an actual value (P _ist ) at an output of the power generation plant, and a controller for tracking the power generation units based on the target value (P _soll ) and the measured actual value (P _ist ). A system for dynamically monitoring a regenerative power generation plant according to claim 1, wherein controlled variables of the control are the active power, the reactive power, the displacement factor, the power factor, the grid frequency and / or the grid voltage. A system for dynamically monitoring a regenerative power generation plant according to claim 1 or 2, wherein the controller processes measured values of the power generation units. A system for dynamically monitoring a regenerative power plant according to any one of claims 1 to 3, comprising one or more interface units for different types of power generation units. System for dynamic monitoring of a regenerative power generation plant according to one of claims 1 to 4, wherein passive power elements of the power generation plant are taken into account in the scheme. A system for dynamically monitoring a regenerative power plant according to any one of claims 1 to 5, comprising a signal output for feedback of information. A system for dynamically monitoring a regenerative power plant according to any one of claims 1 to 6, wherein the control comprises a PID controller. A regenerative power generation plant having a plurality of power generation units, comprising a system for dynamically monitoring the power generation plant according to any one of claims 1 to 7. The regenerative power generation plant according to claim 8, wherein the power generation unit is an inverter. A regenerative power generation plant according to claim 8 or 9, comprising a photovoltaic power generation plant. A method of controlling a regenerative power generation plant having a plurality of power generation units, comprising the steps of: receiving a target value (P _soll ) measuring an actual value (P _ist ) at an output of the power plant, and controlling the power generation units based on the Target value (P _soll ) and the measured actual value (P _ist ).

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