introduction of wide area mesurement syatem
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Introduction of Wide Area Measurements System
Seminar By :Nitesh Pandit
Kedar Khandeparkar
Under The Guidance ofProf. A.M. Kulkarni
Electrical Engineering Dept, IIT Bombay
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1. Introduction 1.1 Power Grid 1.2 WAMS2.Components of WAMS 2.1 PMU 2.2 PDC3. Standards for PMU 3.1 IEEE C37.1184. Communication between PMU & PDC 4.1 UDP Communication 4.1 TCP Communication 5. WAMS Implementations6. Possible Approach7. Conclusion8. References
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Introduction
Power Grid High voltage electric transmission is the bulk transfer of electric
energy, from generating power plants to substations located nearer.
Transmission lines, when interconnected with each other, become high voltage transmission networks these are typically referred to as power grids.
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Wide Area Measurement System (WAMS)
Advanced measurement technology to collect information.
The WAMS technologies are comprised of two major functions: obtaining the data extracting value from it
Getting the data is accomplished with a new generation of data recording hardware that produces high quality and high volume recordings.
Data is extracted and analyzed using several signal analysis tools and algorithms.
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Need Of WAMS
In order to avoid major regional blackouts such as those occurred in North America and Canada in 2003.
When constant monitoring applications are available immediate action can be taken if some failures are detected.
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Comparison of SCADA & WAMS
SCADA can only provides steady, low sampling density, and non synchronous information of the network.
Controlling centre cannot know the dynamic operation states of the system.
Instant action cannot be taken in case of failures.
WAMS enables us to observe the power system synchronously in more elaborate time scale.
WAMS requires data to be sent and captured at very fast rate.
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Components of WAMS
Phasor Measurement Unit (PMU)
Phasor Data Concentrator (PDC)
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They are devices which use synchronization signals from the global positioning system (GPS) satellites and provide the phasor voltages and currents measured at a given substation.
A phasor is a complex number that represents both the magnitude and phase angle of the sine waves found in electricity.
PMU can have different Data Rate i.e. 60, 30, 10 frame per second.
PMU
PMUInput
Secondary sides of the 3 P.T. or Φ
C.T.
Corresponding Voltage or
Current phasors
Output
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Advantage of using GPS
It is accurate to within 1 microsecond at any location on earth.
A 1-microsecond error translates into 0.021° for a 60 Hz system and 0.018 ° for a 50 Hz system and is certainly more accurate than any other application.
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PDC
It is a node in a system where phasor data from a number of PMUs or PDCs is correlated and fed out as a single stream to
other applications.
PDC would performs the Real time monitoring , alarming , event triggering.
It performs local archiving.
It performs various quality checks on the phasor data.
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Phasor Data Concentrator (PDC)
PMU 1 PMU 2 PMU 8 PMU 41 PMU 42 PMU 48
PDC 1 PDC 6
Super PDC
DBReal Time
Monitoring
Visualization
Level n
Level 1
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Operations inside PDC
Receive data from PMU's/PDC's
Align the data as per the time tag and then perform sorting
Combine all data from multiple PMU's having same time stamp t into a single frame
Perform Local archival and also send the combined frame to other applications.
PDCs are available as Hardware and Software.
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Time Based Aligning of Data
Algorithm 1An array of time stamped buffers is maintained.
PDC will group together measurements from the same time stamp in to a single buffer.
In some cases the measurements may be delayed so there will be more than one time stamped buffer.
When the buffer is full the PDC will forward it to the applications consuming it.
Drawbacks PDC has to wait for the buffer to be full before forwarding it to the
applications.
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Algorithm 2 Add a time-out per time stamped buffer.
The PDC assigns this newly arrived measurement to a new buffer.
The countdown to the time-out is initiated when the first phasor measurement of a certain time stamp arrives at the PDC.
When the time-out is up the PDC will forward the set without waiting for the rest of the phasor measurements to arrive
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Continue…
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Process Model for Sorting
begin
wait
sort
Send_Set
default
Buffer Fulldefault
Time Out
Received Frame
default
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Standards for PMU
IEEE Std 1344 IEEE C37.118 OPC-DA / OPC-HDA - A Microsoft Windows based interface protocol that is
currently being generalized to use XML and run on non Windows computers.
IEC 61850 a standard for electrical substation automation.
BPA PDCStream - a variant of IEEE 1344 used by the Bonneville Power Administration (BPA) PDCs and user interface software.
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IEEE C37.118
Four message/frame types
1) Command (Binary)2) Configuration (Binary)3) Data (Binary)4) Header (ASCII)
SYNC 2B
FRAMESIZE 2B
IDCODE 2B
SOC 4B
FRACSEC 4B
DATA 1 DATA 2 DATA n CHK
Frame Transmission Order
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1) Command Frame is received by PMU in order to take a particular action. Example “turn ON the transmission of data”.
2) Header frame is human readable/ASCII information about the PMU, the data sources, scaling, algorithms, analog filters used, or other related information.
3) Configuration frame contains the information and processing parameters of the PMU. Like it contains phasor, analog, frequency and digital value of PMU.
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Configuration Frame
Organization
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3) Data frame provides information regarding phasor data and the state of the digital inputs on each channel. It also defines the frequency, angle, over-current, under-voltage and rate of frequency change.
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Communication between PMU & PDC
1) UDP Communication
2) TCP Communication
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UDP Communication
Data Frame
Data Frame
Data Frame
CMD Frame - Send New CFG frame
CFG Frame
Data Frame
Data Frame
CMD Frame -data transmission off
CMD Frame - Send CFG frame
CFG Frame
CMD Frame - Send data frame
Conf change bit (0->1)
CMD Frame - Send data frame
PDC PMU
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TCP Communicatio
n
SYN , Seq=0
Seq=0, Ack=1
Seq=1,Ack=1
CMD Frame - Send CFG frame
Ack = YY
CFG Frame : Seq 22
DATA Frame : Seq 24
CMD Frame - Send Data frame Seq :23
Ack = 23
CMD Frame - Stop Data frame Seq :xx
Ack = 22
FIN
PDC PMU
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WAMS Implementations
OpenPDC
The openPDC is a complete set of applications for processing streaming time-series data in real-time.
The openPDC is based on the SuperPDC which was developed by the Tennesse Valley Authority starting in 2004.
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Wide Area Frequency Monitoring Network (FNET)
It is a GPS-synchronized wide-area frequency measurement network.
Currently, FNET collects data from over 80 FDRs, most of which are installed in the North American power grid.
Applications provided by FNET include event detection and location, oscillation detection visualization.
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Wide Area Frequency Monitoring by IIT Bombay
It is a continuous data archiving system.
It provides Web display of of the archived data.
Work on generating triggers, alarms in case some unusual events occur is in progress.
Currently, frequency measuring sensors are located at Mumbai, Kharagpur and Ahmedabad.
http://www.wafms.co.cc/
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Other Implementations
ePDC
SEL
TNB
KalkiTech
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PDC Product Comparison Chart
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Possible Approach
We have considered TCP/UDP as network communication protocol.
Client Server Architecture.
State Diagram :
PDC : Process 1
PDC : Process 2
PMU Simulator
CMD FRM - send CFG Frame
CFG FRM
CMD FRM - send DATADATA FRM
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PDC Process 2 Details
Shared Memory
CFG frames
Receive data/cnf frames
Match
Create data nodes Sort()
Maintains Buffer List
Pass_ to_ upper_ Layer()
Archive()
History
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Conclusion
Synchronized phasor measurement technologies have proliferated in many countries all over the world.
With the spread and advancement in this technology real time monitoring and decision making is going to be much easier.
Development of free and open source PDC software will certainly boost more contributions from all over the world.
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References
Ken Martin, “IEEE Standard for Synchrophasors for Power Systems”, IEEE Std C37.118 -2005 (Revision of IEEE Std 1344-1995).
“Real Time Wide-Area Monitoring, Control and Protection”, EIPP Real Time Task Team, White Paper DRAFT 3: Wide Area Monitoring-Control Phasor Data Requirements.
Andrew Armenia, “A Flexible Phasor Data Concentrator Design Leveraging Existing Software
Technologies”, IEEE TRANSACTIONS ON SMART GRID, VOL. 1, NO. 1, JUNE 2010. Biju Naduvathuparambil, Matthew C. Valenti and Ali FeXiachi, “Communication Delays in Wide Area
Measurement Systems”, Lane Dept. of Comp. Sci. & Elect. Eng., West Virginia University, WV. Basics of Electric Power Transmission and Grid technology
http://en.wikipedia.org/wiki/Electric_power_transmission. http://www.phasor-rtdms.com/phaserconcepts/phasor_adv_faq.html#Question9.
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Thank you
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