The German FNN Steuerbox Version 1.4 (official) is available for just 39 Euro!

The officially published FNN Steuerbox specification (in German only) is available for immediate download (of a personalized pdf) ... if you pay 39 Euro ... really affordable!

The Steuerbox uses a subset of IEC 61850 models and services ... check it:

https://www.vde-verlag.de/buecher/636412/lastenheft-steuerbox.html

The document contains a link (on the last page) to additional material: ICD File, certificate and settings XSDs ... WOW ...

This is one of the great news: to get the material for almost free!

In the History element of the ICD file you can see that my granddaughter Jana and I have been involved ...  

Enjoy

IEC is about to prepare the "Use of IEC 61850 for electrical energy storage systems"

IEC TC 57 has just sent a 75+ pages draft document for comments by the national committees:

Draft IEC TR 61850-90-9 – Communication networks and systems for power utility automation – Part 90-9: Use of IEC 61850 for electrical energy storage systems

See: 57/1715/DC

The document is a very comprehensive document that provides a list of use-cases and solutions on how to use and extend the IEC 61850 models for electrical energy storage systems.

The



It is recommended for the various stakeholders to get more deeply involved into the further steps to get a standard information model for electrical storage systems!!

Sample use-case:



This document fits well into the set of drafts that are needed for power distribution systems.

More to come!

PV Power to (de)stabilize the European Power Delivery System?

One swallow does not make a summer – But 100.000 do. One PV system on a roof in the nineties did not make a smart grid based on renewable resources. But due to the growth of renewable resources like PV the power delivery system changes a lot. Usually today the PV inverters do automatically frequency disconnection.

ENTSO-E the “European Network of Transmission System Operators for Electricity” noted in a letter to Commissioner Oettinger of the European Commission that too many “swallows” are flying somehow “uncontrolled” – flying alone … not being aware what’s going on around them … not seeing the system (!):

“This letter is to brief you on a security of supply issue arising from the automatic frequency disconnection settings of installed photovoltaic (PV) panels in some European countries and to request your support in encouraging the national Regulatory authorities in impacted countries to facilitate the timely implementation of remedial actions.

Due to the interconnected nature of the transmission system until such remedial actions are implemented the synchronous Central European power system is at increased risk to significant frequency deviations of a magnitude that would generate a widespread loss of supply.

In several European countries, connection standards applicable to photovoltaic panels and other distributed generation have been or are still specifying that the panels automatically disconnect from the grid whenever the system frequency reaches 0.2 or 0.3 Hz deviations from the required normal value of 50.0 Hz.

Current information from our Member TSOs, including for example Germany and Italy, indicate that the significant growth in photovoltaics in recent years has resulted in a PV installed capacity (with such settings) approaching 25 000 MW. At these levels there is clearly a risk of an instantaneous generation loss far in excess of the 3000MW generation loss „ride-through‟ design limit for the Continental European system. …”

Click HERE for the letter from ENTSO-E [English, pdf]

Ok, what to do now? Act! There are many actions needed to get CONTROL over the system in the future system based on many distributed resources! One aspect is to change limits … but more important is the control of the power resources.

A group of IEC TC 57 WG 17 is working on a very crucial part of IEC 61850: Draft IEC 61850-90-7 TR – “Communication networks and systems for power utility automation – Part 90-7: IEC 61850 object models for photovoltaic, storage, and other DER inverters” (57/1155/DC).

Major PV inverter manufacturers and other experts have drafted the above document.

Crucial aspects covered by 90-7 (in addition to IEC 61850-7-420 – DER) are:

7. DER management functions for inverters.

7.1 Immediate control functions for inverters
7.1.1 Function INV1: connect / disconnect from grid
7.1.2 Function INV2: adjust maximum generation level up/down
7.1.3 Function INV3: adjust power factor.
7.1.4 Function INV4: request real power (charge or discharge storage)
7.1.5 Function INV5: pricing signal for charge/discharge action

7.2 Modes for volt-VAr management
7.2.1 Var management modes using volt/VAr arrays
7.2.2 Volt-VAr mode VV11: normal energy conservation mode
7.2.3 Volt-VAr mode VV12: maximum VAr support mode
7.2.4 Volt-VAr mode VV13: static inverter mode
7.2.5 Volt-VAr mode VV14: passive mode.

7.3 Modes for frequency-related behaviours
7.3.1 Frequency management modes
7.3.2 Frequency-watt mode FW21: high frequency reduces active power.
7.3.3 Frequency-watt mode FW22: constraining generating/charging by frequency (see diagram below)

7.4 Dynamic grid support during abnormally high or low voltage levels
7.4.1 Dynamic grid support mode TV31: dynamic grid support during abnormally high or low voltage levels
7.4.2 Example of dynamic grid support capabilities.

7.5 Functions for “must disconnect” and “must stay connected” zones
7.5.1 “Must disconnect” MD curve
7.5.2 “Must stay connected” MSC curve

7.6 Modes for watt-triggered behaviours
7.6.1 Watt-power factor mode WP41: feeding power controls power factor

7.7 Modes for voltage-watt management.
7.7.1 Voltage-watt mode VW51: voltage-watt management: generating by voltage
7.7.2 Voltage-watt mode VW52: voltage-watt management: charging by voltage

7.8 Modes for behaviours triggered by non-power parameters
7.8.1 Temperature mode TMP
7.8.2 Pricing signal mode PS

7.9 Setting and reporting functions
7.9.1 Establishing settings DS91: modify inverter-based DER settings
7.9.2 Event logging DS92: log alarms and events, retrieve logs
7.9.3 Reporting status DS93: selecting status points, establishing reporting mechanisms
7.9.4 Time synchronization DS94: time synchronization requirements

Example (without further explanations):

7.3.3 Frequency-watt mode FW22: constraining generating/charging by frequency:

It is expected that this part IEC 61850-90-7 is one of the crucial parts of IEC 61850 for the stability of the future power delivery systems all over.

It’s “PV summer time” – there are millions of PV inverter installed (most of them are not controlled … just “flying” around.

Please contact your national IEC TC 57 committee to get a copy of the document.

Click HERE for an interesting ENTSO-E Draft “Requirements for Grid Connection Applicable to all Generators” dated 22 March 2011

The Power Systems are quite comprehensive … and complex!

Growth of Substation Automation with IEC 61850

There seems to be an ongoing interest in doing market studies in order to figure out what will be the technologies applied in power system automation in the next years or decades. One of the latest is the following report:

"The World Market for Substation Automation and Integration Programs in Electric Utilities: 2011-2013." by Newton-Evans Research Company

Click HERE for a brief news information found on the Newton-Evans website.
Click HERE for some details from the report from Business Wire.

The number of systems installed in the electrical power delivery systems is much bigger than what these kind of studies show. The news reports: "Respondents indicated a total of 1,567 transmission substations and 5,154 distribution substations in operation as of the 4th quarter of 2010. These represent a 9% sample of U.S. and Canadian combined totals of transmission voltage substations and nearly 10% of all distribution voltage substations."

The power market is a global market - the potential market for IEC 61850 is global as well! The numbers of applications is in the Millions! Check what Enel reported during the recent first European IEEE Smart Grid conference in Gothenburg (Sweden): Enel owns over 0.4 MILLION MV/LV Substations! HV and MV network are remotely operated, more than 0.1 MILLION MV substations remote controlled ... There is a potential of 0.3 MILLION LV substations where IEC 61850 one way or the other may be used in the next decade.

One of Enel's project deals with even more potential use cases of IEC 61850:

Active Control of Distributed Energy Resources (DER) connected to the Medium Voltage network: The project will deal with:

• Realizing an advanced control system
• Implementing an “always on” and standard-based communication solution connecting all the relevant nodes in the network, including DER locations.
• Implementing Voltage Control (at all nodes) and Power Flow Control in the MV network.

Click HERE for the complete presentation by Enel.

Take, for example, the number of PV inverter manufactured monthly by one vendor: SMA (Germany):

"On the reporting date, SMA had a maximum annual production capacity of approx. 11 GW worldwide. This corresponds to a doubling in annual production capacity in comparison to the end of 2009. Owing to the better availability of electronic components, SMA was able to utilize almost fully its existing production capacities in the third quarter of 2010 with an inverter output sold of nearly 2.6 GW. In the first nine months, SMA sold inverter output of 5,738 MW in total" ... I guess this means some 500.000 PV Inverters from one manufacturer (assuming average inverter of 20 kW) !!

Click HERE for the SMA news report.

Taking the monitoring, control and automation needs reported by Enel (above) into account means: there is a potential global market of MILLIONS of devices per year that need "standard-based communication". IEC 61850 has almost everything needed.

In this light we have to look at what Newton-Evans figured out:

"Of 5,154 distribution substations in operation at participating utilities, nearly 36% were reported to be without any automation. Just over one-half (52%) of these distribution substations were classified as Stage 1 sites (having some IEDs, RTUs, and two-way communications). About 12% were reported to be “fully automated.”"

When we talk about "standard-based communication", we have to use a wide-angle lens - not a zoom lens to focus on some substations in the U.S. There are definitely a lot more of opportunities globally!

There is a bright future for IEC 61850!

Active and Reactive Power Control with IEC 61400-25-2

The focus of the IEC 61400-25 series is on the communications between wind power plant components such as wind turbines and actors such as SCADA systems. IEC 61400-25-2 specifies the information model of devices and functions related to wind power plant applications. These models extend IEC 61850-7-x models. Almost all definitions, hardware and software solutions available for IEC 61850 can be used for IEC 61400-25-2. In particular, IEC 61400-25-2 specifies the compatible logical node names, and data names for communication between wind power plant components.

The standard IEC 61400-25-2 defines a comprehensive list of information models (Logical Nodes) for wind turbines, e.g.:

• WTUR - Wind turbine general information
• WROT - Wind turbine rotor information
• WTRM - Wind turbine transmission information
• WGEN - Wind turbine generator information
• WCNV - Wind turbine converter information
• WTRF - Wind turbine transformer information
• WNAC - Wind turbine nacelle information
• WYAW - Wind turbine yawing information
• WTOW - Wind turbine tower information

The most crucial Logical Nodes are likely the

• WAPC - Wind power plant active power control information
• WRPC - Wind power plant reactive power control information

These models describe the "interface" between a complete park and the grid operator for control purposes. These Logical Nodes can be used for other power resources like CHP, PV, ... The German EEG (Erneuerbare-Energien-Gesetz) accelerates the application of IEC 61400-25 tremendously, because the Grid Operator needs more information about the park and he needs to control the whole power system in cases of faults and critical conditions - wind power plants and other resources are an integrated part of the whole system. These resources cannot be treated just as negative loads.

The WAPC (active power control) comprises the following Data Objects:

Status information

• Actual number of wind turbines in operation
• Active Power Limitation Mode Enabled
• Active Power Control Mode Enabled controlling apparent power
• Gradient Function Enabled
• Delta Function Enabled

Measurements

• Wind Power Plant active power output capability
• Wind Power Plant active power output
• Wind Power Plant apparent power
• Wind Power Plant Gradient
• Wind Power Plant active power reserve utilizing the Delta function –
  the difference between active power generation capability and active
  power generated

Control information

• Activate active power control function
• Activate apparent power control function
• Activate gradient control function
• Activate delta control function
• Set reference value for the wind power plant active power output
• Set reference value for the wind power plant apparent power output
• Set reference value for gradient ramping up the wind power plant active power output
• Set reference value for gradient ramping down the wind power plant
  active power output
• Set reference value for the wind power plant active power reserve –
  also named as “spinning reserve”

The information provided by these models is crucial for a future stable power delivery system.