1. Recent Trends On Flexible AC Transmission
Systems (FACTS)
Maharshi Pandya(4th sem, EE, Indus University)
Mayank Patel(4th sem, EE, Indus University)
Note: This Presentation based on Review About FACTS. Not Any other Research.
2. Outline
• Overview Of The Transmission Planning Process
• Role Of Power Electronics Device In Power System
• Introduction Of FACTS
• Benefits Of FACTS Technology
• Types Of FACTS Controllers
• Recants uses FACTS devices
• Conclusion
• References
3. Overview Of The Transmission Planning
Process
• Is A Very Complex Process And Recent Trends And Challenges Make It Even
More Complicated In the past, before the electricity market liberalization.
• Its aim to minimize the generation costs.
• minimizing transmission costs (investment and operation).
• Use of static and dynamic technical constraints.
4. Role Of Power Electronics Device In
Power System
• Switching operation because Availability Of High Power Semiconductor
Devices
• Decentralized Renewable Energy Generation Sources
• Increased Power Transfer With Existing Transmission System
• Effective Control Of Power Flow Needed In A Deregulated Environment
• Norms For Power Quality
5. Introduction On FACTS
• Flexible AC Transmission Systems (FACTS) are the name given to the
application of power electronics devices to control the power flows and
other quantities in power systems.
• “Alternating current transmission systems incorporating power
electronic based and other static controllers to enhance controllability
and increase power transfer capability.”
• The design of the different schemes and configurations of FACTS
devices is based on the combination of traditional power system
components (such as transformers, reactors, switches, and capacitors)
with power electronics elements (such as various types of transistors and
thyristors)
6. Benefits of FACTS
• To increase the power transfer capability of transmission networks.
• To provide direct control of power flow over designated
transmission routes.
• Control of power flow as ordered so that it follows on the prescribed
transmission corridors.
• Increase the loading capability of lines to their thermal
capabilities
7. FACTS CONTROLLERS
SHUN
T
• Static Var Compensator
• Static Synchronous Compensator
• STATCOM
SERIE
S
• Thyristor Controlled Series Compensator (TCSC)
• Static Synchronous Series Compensator
• Fault Current Limiter (SC+FPD)
HYBRID
• Dynamic Power Flow Controller (DFC)
• HVDC Light/HVDCLightB2B/UPFC
9. Static Var Compensator
• The SVC is an excellent tool for achieving dynamic voltage
control of power systems. Increased efficiency in power
systems
• The global trend is towards ever larger power networks,
longer transmission lines, and higher consumption. Energy
is also becoming increasingly expensive. To cope, power
transmission and distribution systems have to become more
efficient. It has increasing power transmission and
distribution capacity at a lower cost.
10. SVC used as a voltage stabilization
• SVC is the preferred tool for dynamic reactive power support in high
voltage transmission grids. it will counteract the often hazardous voltage
depressions that follow in conjunction with faults in the grid. These highly
dynamic events, where the ever increasing use of induction motors (like
those in air-conditioning units and wind power turbine-generators) stresses
the grid, will need an SVC to maintain the grid voltage and safeguard the
fault ride-through capability.
• Static var compensator includes the following major components
1. Control system
2. Thyristor valves
3. Capacitor banks
4. reactors
11. Basic SVC schemes
• Thyristor controlled reactor and fixed capacitor,
TCR/FC TCR/FCs are characterized by
– Continuous control
– No transients
– Elimination of harmonics by tuning the FCs as filters
– Compact design
• Thyristor switched capacitor, TSC
TSCs are characterized by
– Stepped control
– No transients
– No harmonics
– Low losses
– Redundancy and flexibility
12. Cont.…
• Thyristor controlled reactor/Thyristor switched capacitor, TCR/TSC
TCR/TSC combinations are characterized by
– Continuous control
– No transients
– Elimination of harmonics via filters or TSR control
– Low losses
– Redundancy
– Flexible control and operation
13. The Benefits Of SVC To Power
Transmission
• Stabilized voltages in weak systems
• Reduced transmission losses
• Increased transmission capacity, to reduce, defer or eliminate the need for new lines.
• Higher transient stability limit
• Increased damping of minor disturbances
• Greater voltage control and stability
• Power oscillation damping.
15. TCSC (Thyristor controlled series capacitor)
• The TCSC behaves as a tunable parallel LC-circuit to the line current. As
the impedance of XL is varied from its maximum (infinity) toward its
minimum wL, the TCSC increases its capacitive impedance
17. UPFC (Unified Power Flow Controllers)
• The Most Complete And Versatile (And Costly) FACTS Device Is The UPFC, Able To Independently And
Simultaneously Control Active Power Flow, Reactive Power Flow And Nodal Voltage Magnitude. The
UPFC Has Been So Far Applied Only In Three Installations Worldwide (Two In The United States, One
In South Korea)
18. Device Capabilities
Device capabilities SVC STATCOM TCSC SSSC TCPST UPFC
Transmission Capacity Small Small Strong Strong Strong Strong
Power Flow Control Small Small Medium Strong Medium Strong
Transient Stability Small Medium Strong Strong Medium Strong
Voltage stability Strong Strong Small Small Small Strong
Power Oscillation
Damping
Medium Medium Medium Medium Medium Strong
Control of Wind Farm
Reactive Power O/p
Yes Yes No No No Yes
Investment Cost Small Medium Small Medium Medium Strong
19. Conclusion
• The above discussion reflects various work and philophies are
covered in the area of FACTS. The potential role that FACT may
play towards the development of the future Indian transmission
system. In fact, FACT elements may provide Indian TSOs with
effective solutions to the several criticalities they encounter. Finally,
it has to be noted that in a highly meshed network, as the Indian
FACTS become extensively deployed, they will deliver real benefits
only when subjected to a coordinated and hierarchical control.
20. Reference
[1] BOOK POWER GENERATION ENGINEERING. AUTHOR R.P AJWALIA
(ATUL PARAKASHAN)
[2] A. L’ABBATE, G. MIGLIAVACCA, U. HÄGER X, C. REHTANZ X ERSE
(ENEA - RICERCA SUL SISTEMA ELETTRICO) [FORMER CESI RICERCA]
SPA, MILAN, ITALY TECHNICAL UNIVERSITY OF DORTMUND,
DORTMUND, GERMANY
[3] EUROPEAN TRANSMISSION SYSTEM
[4] V. KAKKAR, HEAD OF DEPTT (EEE), AND N. K. AGARWAL, ASSIST.
PROF. (EEE) VITS GHAZIABAD.
[5] L. GYUGYI, N.G. HINGORANI, “UNDERSTANDING FACTS,”
IEEE PRESS, 1ST EDITION, DECEMBER 1999.
[6] M.H. RASHID, “POWER ELECTRONICS,” PRENTICE HALL, 3RD
EDITION, 2004.