Smart Distributed Control of Power Systems
Deepak Divan Ron Harley School of Electrical Engineering
Georgia Institute of Technology, Atlanta, GA, USA
777 Atlantic Drive [email protected], GA
Confidential
US Power Grid: Problems (Opportunities)
• Grid is seeing increasing congestion and degraded reliability
• Uncontrolled power flow is a major issue for transmission & distribution
• Building new transmission/distribution lines is no longer a simple process
• First line to reach thermal rating limits system transfer capacity, even as neighboring lines are under-utilized
• Real situation is worse as reliability has to be ensured with (N-X) contingencies
• Lack of visibility and control leads to conservative operation resulting in significant under-utilization of assets
• Possible cascading failures under contingency conditions
• Reliability, load growth, will be major drivers for new investments
Power flow path from Wisconsin to TVA*
*Courtesy: Tom Overbye, UIUC
j16 Ω
j24 Ω
138kV∠0°
138kV∠7.75°675A
450A
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Proposed Vision for Electricity Infrastructure Research
The Vision:A fully controllable electricity delivery infrastructure that is cost-effective, provides flexible interconnection of sources and loads, is robust and reliable, is self-healing and degrades gracefully under contingencies, enables operation of market forces, never degrades system reliability to worse than current levels, and is scalable to meet societal requirements of growth and sustainability.
How Will This Be Implemented?• Power delivery assets will have to be infused with intelligence, communications and control capability, using distributed mass-manufactured components for low-cost and high-reliability through redundancy.
• Power grid will be massively-networked for high-reliability, and will allow autonomous local control with local information while ensuring global system level optimization using feedback.
• New techniques for system level monitoring, visualization, protection and control in the presence of massive data streams from widely distributed assets will provide visibility and actionable information to allow operators to avert catastrophic events.
• This approach can dramatically reduce the cost and accelerate implementation of a Smart Grid, enabling system transforming applications such as PHEVs, demand side management, and support proliferation of distributed renewable resources that foster sustainability.
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Thin AC Converters – Making Existing Grid Assets Controllable
• Proposed approach provides static and dynamic control of value of existing grid assets, such as shunt VAR capacitors and transformers
• Allows operation in ‘dispatch’ mode or under local control to regulate voltage or respond to faults
• Direct AC conversion using semiconductor switches, small LC filters, switchgear and minimal energy storage allowing compact size, low volume and low cost
• Imposes minimal additional stresses on the asset allowing use in retrofit applications.
• ‘Fail Normal’ mode of operation, where failure of the thin converter automatically restores normal function of the asset on the grid
• Multi-Level AC Converter allows transformer- less operation in medium voltage applications
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Thin AC Converters
THIN AC CONVERTERS
MULTI-LEVEL DIRECT AC CONVERTERS
VIRTUAL QUADRATURE SOURCES
Possible ApplicationsPossible Applications
LTC TransformersShunt VAR Capacitors Transmission Lines
Inverter-less STATCOMs Controllable Network Transformers
Smart Wires
http://www.tradesurinc.com/productshttp://www.vatransformer.com
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Distributed FACTS for Power Flow Control• Distributed FACTS suggested by Divan – Smart Wires
– Provide the functionality of FACTS at lower cost and high reliability
– Series VAR injection controls effective line impedance & real power flow– Large number of modules float electrically and mechanically on the line– Can be incrementally deployed to provide controllable power flow– Standard low-cost mass-manufactured modules– Redundancy gives high reliability and availability– Phase I supported by TVA, Con Ed, DOE and others
D-FACTS
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sXVVP =
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Active Smart Wires
• Distributed Static Series Compensator (DSSC)– Active solution employing a synchronous voltage source inverter– Each module rated for 5 KVA (capable of injecting ± 4.6 V @ 1000 A)– Communication interface is required to realize the bi-directional control– Can be made larger for distribution applications (one per line)
Power supply
Main transformer
Filter
PWM Inverter
DC Capacitor
V
ControlsCommunication
Module
Current feedback
Line Current
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Distributed Series Reactance – Passive Smart Wires
• Simplest implementation of DSI, with inductive impedance injection (Current Limiting Conductor or CLiC) – functions as a current limiting system
• As current in a line approaches the thermal limit, CLiC modules incrementally turn on, diverting current to other under-utilized lines
• Each module is triggered at a predefined set point to reflect a gradual increase in line impedance
• No communication required and the devices operate autonomously
Control
Power Line
Transformer
S1
XM
Power Supply
SM
I0 Ithermal
Line Current (ILine)
N Xm
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Increase in System Capacity With DSR Modules
0 0.5 1 1.5 2 2.50
0.25
0.5
0.75
1
Time (sec)
Line
Cur
rent
(KA)
Profile of Line 2 Current
DSR Active
548.7 A
750 A
624.2A
GeneratorTaken Off
Simplified Four Bus System
Contingency Condition: Generator Outage
20 40 60 80 100 120 140 160
20
40
60
80
100
120
140
160
180
Load2 (MW)
Load
1 (MW
)
Line2 Overload
Line5 Overload
Line2 Overload
Line2, Line5Overload
Line1, Line2,Line5 Overload
Line2, Line4 Overload
Line1, Line2, Line4, Line5 Overload
A
A'
B
B'
C'
C
System Capacity with DSI/DSR ModulesBlue: Normal, Red: DSR, Green:DSI
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Increase in Network Utilization
IEEE 39 Bus System
Network Performance With CLiC
Line
2_3
Line
6_5
Line
6_7
Line
9_39
Line
10_1
3
Line
12_1
1
Line
13_1
4
Line
19_1
6
Line
22_2
1
Line
23_2
4
Line
25_2
6
Line
26_2
7
Line
29_2
6
Line
29_2
8
Power Lines
Line
Cur
rent
s (%
Ther
mal
Lim
it)
0
20
40
60
80
100
Line currents with CLiCLine currents without CLiC
Increase in utilization from 59% to 93.3% for 14 lines
G1
G8
G10
230
1
G2
G3
G9
G4G5
G6
G7
39
9
8 7
5
4
3
18
37
25
17
26 28 29
38
24
27
15
14
12
13
1011
32 34
20
19
21 2235
23
36
16
6
31
22.76 MVAR
19.52 MVAR
18.77 MVAR
14.75 MVAR12.64 MVAR
3.52 MVAR
12.86 MVAR
12.04 MVAR
9.15 MVAR
• Increase in Transfer Capacity from 1904 MWs to 2542 MWs (congested corridors and the required MVARs are shown by red lines)
• With (N-1) contingency, capacity is increased from 1469 MW to 2300 MW without building additional lines
• Would require 9 additional lines to realize capacity increase
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DSR Prototype
Complete module with the casing • Electrical– Operating Level : 161 KV, 1,000 A– ACSR Conductor: Drake (795 Kcmil)– Injection: 10 kVA
• Mechanical– Target weight per module: 120 lb– Packaging to avoid corona discharge,
and other mechanical, thermal and environmental issues
• Simple low-cost design suitable for mass manufacturing
• Suitable for distribution and transmission applications
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Validation at High Voltage and Current
Corona inception: 125 kV Extinction: 123 kV
Photograph correspond to 166 kV
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Smart Wires in a Smart Grid
• It is proposed that the use of distributed solutions based on low-power power electronics can allow utilities to move towards dynamically controllable meshed grids, significantly enhancing grid reliability, capacity and utilization. This can enable:
• Improved reliability without having to build new lines
• Improved dynamic coordination between regions
• Reduction in dynamic capacity reserve for generators
• Possibility of moving power along a predetermined contract path
• Can be applied at the transmission, sub-transmission and distribution levels.
• Can be layered incrementally onto the existing infrastructure as desired, and will not degrade the inherent reliability of the existing system.
• Makes the grid self-healing, automatically maintaining safe operating levels even in the face of contingencies.• Funding such investments on the basis of congestion relief is problematic in regulated
environments, new mechanisms may have to be found.