Download - HVDC Grid Challenges Locks and Opportunities
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HVDC Grid Challenges Locks and Opportunities
Seddik BACHA , ProfessorSuperGrid Institute
Grenoble –Alpes University/ G2Elab
Power Electronics issues overview
Keynote
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2May 2021
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Table of contents
Introduction : drivers to HVDC
Some historic facts and some achievements
HVAC vs HVDC
LCC vs VSC
DC/DC
DC breakers
Some Locks and Research Trends
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Table of contents
Introduction : drivers to HVDC
Some historic facts and some achievements
HVAC vs HVDC
LCC vs VSC
DC/DC
DC breakers
Some Locks and Research Trends
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Introduction : drivers to HVDC
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New requirement due to
Bulk power long distance (China, Brasil, India)
Increasing transmission capacity
Needs to control massive energy flows (congestions avoiding, losses mitigation)
Power market integration, increase of exhanges
Increasing the Renewables integration
Enhancing the solidarity between no synchronized areas
Off-shore generation integration :more installed power, farer
High capacity submarine transmission cables
Stability issues
Needs for new Ancillary Services provision
Needs fo more flexibility
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Introduction : drivers to HVDC
Limitations of the classical HVAC systemImpossibility to connect no synchronized AC Grids with different Frequencies
Possibly large inter area oscillations when connecting two AC grids with same Frequencies and Voltages
Limited distances due to :Inductive behavior of overhead lines
Capacitive behavior of cables
The power flows are guided by the minimum impedance paths
Conclusion : the previous requirements cannot be addressed
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Introduction : drivers to HVDC
Solutions :
1. Actual HVAC system reinforcement by:
Adding new overhead lines
Using widely FACTS systems
2. Building in parallel a new HVDC System
3. Hybridation
Source B. Jacobson Développements in Multiterminal HVDC , IEEE EPEC , Winnipeg , Manitoba , Oct 11, 2011
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Introduction : drivers to HVDC
© IFHT© IFHT
10 W
0
10 E
20 E
30 E
40 N
50 N
60 N
70 N
HVAC + FACTS
Solution
New HVAC
Existing line
New HVDC
From IRENE 40.eu
Future European Energy Network 7FP
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Introduction : drivers to HVDC
New HVACExisting line
New HVDC
HVDC Solution
From IRENE 40.eu
Future European Energy Network 7FP
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Table of contents
Introduction : drivers to HVDC
Some historic facts and some achievements
HVAC vs HVDC
LCC vs VSC
DC/DC
DC breakers
Some Locks and Research Trends
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Some historic facts and some achievements
mercury-arc valve 1901
First HVDC Project Gotland 1 in Sweden 1954 : Submarine cable , mercury-arc valves , 30 MW , 150 kV
Last built : 1972 Nelson River 1 plant (Manitoba) 150 kV, 1800 A
Last in operation : 8/2012 : HVDC Inter_Island , New Zeland
Images for wikipedia
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Some historic facts and some achievements
Thyristor « Silicon Controlled Rectifier (SCR) by W. Shockley ,1950
First built : Back to Back plant Eel River (Canada) , +/- 80kV, 320 MW, 2kA , 4800 thyristors (1972) Upgraded 2014
Ongoing technology. Example of Jinping-Sunan Line
Commissioned in 2013
LCC Technology, 7200 MW , ±800 kV, 2090 km
Images for wikipedia
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Some historic facts and some achievements
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IGBT : Insulated Gate Bipolar Transistor , 1978-1979
Ex : INELFE (INterconnexion ELectrique France-Espagne)
2* 1000 MW; +/- 320 kV, cables
MMC converter
http://www.inelfe.eu/IMG/pdf/Spain_France_electrical_interconnection_ENG-compressed.pdf
285 A / 6500 V
1200 A / 3300 V
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Table of contents
Introduction : drivers to HVDC
Some historic facts and some achievements
HVAC vs HVDC
LCC vs VSC
DC/DC
DC breakers
Some Locks and Research Trends
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HVAC vs HVDC (not exhaustive)
Limitations of the classical HVAC systemImpossibility to connect no synchronized AC Grids with different Frequencies/voltages
Impossibility to control the power flows
HVDC Fast control
Coupling AC grids
Power flow controls
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HVAC vs HVDC (not exhaustive)
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Limitations of the classical HVAC systemLimited distances and capacity due to :
Inductive/capacitive behavior of overhead lines
Capacitive behavior of cables
HVDC No impedance effect
Possibility to use cables for long distances power transmission
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HVAC vs HVDC (not exhaustive)
However HVDC requires :Special protection system, including Breakers and Surge Arresters
More CAPEX due to the conversion systems
More losses
Special AC Filters and Reactive Power compensation (LCC technology)
To be integrated on an existing system with dedicated rules and operation (Interoperability)
To fulfill with existing standards an new ones (some of them are not stabilized)
To pay attention to the Short Circuit Ration decrease….
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HVAC vs HVDC (not exhaustive)
Off course , the HVDC power electronics can provide huge advantages by using the converters capabilities ( FACTS functions, Disturbance decoupling , contributions to ancillary services ,…
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Table of contents
Introduction : drivers to HVDC
Some historic facts and some achievements
HVAC vs HVDC
LCC vs VSC
DC/DC
DC breakers
Some Locks and Research Trends
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LCC vs VSC
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LCC vs VSC
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…At the beginning : the LCC
Thystor based technology
Source : Techniques de l’ingénieur
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LCC vs VSC
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LCC some issues
The Reactive Power consumption vs Active Power transmission
Necessity of reactive power compensation
Low frequency harmonics, must be filtered
The energy transit control is done by the action on the firing angles
Two degrees of freedom (the two control angles)
To avoid the inverter loss control its firing angle q is limited between 90° to 150°
The overlapping phenomenon have to be considered
The reversibility is not easy (the current is unidirectionnal and changing the voltage sign…).
Not adapted for grid forming
Not adapted for DC Meshed grids.
BUT : CHEAPER and MATURE TECHNOLOGY
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LCC vs VSC
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The LCC Based HVDC links
Monopole , ground return :
The power is transmitted from one converter station to another station through one conductor (positive or negative polarity) and return is grounded at both stationsMonopole , metalic return : the same but through one conductor and metallic conductor is used as return and grounded at one end
Bipolar : Both poles transmit a power in same direction. It is grounded at both stations. Both poles are operating at equal currents during steady state, therefore zero current through the ground. It can be operating as a single pole during fault at another pole
Back to back : The LCCs are located at the same area , suitable for connecting no synchronous area
Source : The ABC’s of HVDC Transmission Technologies , M.P. Bahrman et al, IEEE Power and energy Magazine 2007
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LCC vs VSC
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… The rising technology
With only three drawbacks : more CAPEX/OPEX*, more losses , less return of experience
The architectures are based on the components association and/or modules associations (ex of Aternate Arm Converter
* The CAPEX and OPEX are disputable
Transistor based technology
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LCC vs VSC
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The MMC : the Army Swiss Knife!
Clean waveforms
Low sub modules frequency operation
No theoretical limits for Voltage/Power ratings
Internal storage possible exploitation
DC/AC disturbances damping
The use as a FACTS for AC benefits
Stability issues purpose
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Topology of 3-phase MMC
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MMC sub module
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LCC vs VSC
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The MMC control is a little bit more complex due to : modules and internal energy balancing
Main control objectives:
Control the power flow to the grid
Control the converter energy balance (𝑃𝐴𝐶𝑎𝑟𝑚 = 𝑃𝐷𝐶𝑎𝑟𝑚 on each arm)
High Level controlLow Level control
Power Ctrl
Arm Energy Ctrl (σ𝑣𝐶𝑆𝑀𝑖
)
Outer Loops
AC and DC
current Ctrl
Inner Loops
Modulation Technique
Balancing Control
Algorithm (BCA)
𝑃𝐷𝐶∗
𝑊𝑎𝑟𝑚∗
Control DC and AC current circulation
Keep the individual SM capacitor voltages balanced (balancing algorithm)
𝑖𝑎𝑟𝑚∗ 𝑣𝑎𝑟𝑚
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Generate xvolts on arm i
Insert nsub-moduleson arm i
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SM OrdersInsert SMs:• 1,3,11,31…
Bypass SMs:• 2,4,5,6…
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Table of contents
Introduction : drivers to HVDC
Some historic facts and some achievements
HVAC vs HVDC
LCC vs VSC
DC/DC
DC breakers
Some Locks and Research Trends
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DC/DC
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Another way to mesh the point to point HVDC transmission system is to create DC/DC links between
There is a large field of possible solutions
Classification by circuit families
Main trend: Modular MultilevelStructures
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DC/DC
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Two MMC based DC/DC HVDC converters
Front-to-front MMC (F2F-MMC) Could be isolated or not
*Three phases are considered as example but both circuits can operate with different number of phases
DC- MMC (close to chopper framework)
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Table of contents
Introduction : drivers to HVDC
Some historic facts and some achievements
HVAC vs HVDC
LCC vs VSC
DC/DC
DC breakers
Some Locks and Research Trends
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DC breakers
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These devices are included in the presentation due to the very important role of Power Electronics as a necessary component
Contrary to AC currents, there is no zero cross over of the fault current
In consequence it is necessary to extinguish this current directly via special switches of by creating a deviation via an oscillating circuit (current deviation or reverse voltage imposition)
Two kind of PE switches are used ; Thyristors and IGBTs
These circuits can be placed in series or in parallel
Usually are associated with Mechanical Switches
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DC breakers
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DC Breakers a classification attempt
DC
CB
Mechanical Disconnector (MD) base
Commutation of faulty current
inverse voltage implementation in Series with
MD
Constant volateg Arrester
Transient voltage LC circuit
inverse voltage implementation in parallel
with MD
current pulseinjection/generation/creation
in parallel with MD
Semiconductor in series with MD
Non-commutationCurrent injection in series
with MD
Solid state breaker Using semiconductors Opening of semiconductors
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DC breakers
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DC Breakers examples
ABB Model : based on energy dissipation
Inverse voltage implementation vis an oscillating circuit
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Table of contents
Introduction : drivers to HVDC
Some historic facts and some achievements
HVAC vs HVDC
LCC vs VSC
DC/DC
DC breakers
Some Locks and Research Trends
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Conclusion : Some locks and research trends
General lock : lack of return of experience for modern technologies
Operation DC/AC interaction mastering
New ancillary services
Losses mitigation
Interoperability with the existent system
Very rapid modes to face
TechnologyNew components integration
HVDC Breakers
HVDC Cables
HVDC insulation and earthing
Measurements ,sensors
CAPEX, OPEX reduction