Superconductor Technologies for Electric Power...
Transcript of Superconductor Technologies for Electric Power...
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Superconductor Technologies forElectric Power Systems
Antonio MorandiDEI Guglielmo MarconiDep. of Electrical, Electronic andInformation Engineering
University of Bologna, Italy
Brazilian Symposium on Power SystemsWednesday, May 16, 2018Niteroi RJ – Brazil
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• The state of the art of practical HTS materials
• Superconductor Technology for power systems• Fault current limiters
• Power Cables
• Energy Storage (SMES and Flywheels)
• Conclusion
Outline
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I am very grateful for their inputs and comments to
• Prof. Mathias Noe, Karlsruhe Institute of Technology, Germany
• Prof. Minwon Park, Changwong University, Korea
• Dr. Tabea Arndt - SIEMENS, Germany
• Dr. Luciano Martini and Giuliano Angeli - RSE, Italy
• Dr. Xavier Granados - ICMAT, Barcelona, Spain
• Prof. João Murta Pina - New University of Lisbon, Portugal
Aknowledgments
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• MetalsNb 9.25 KTc 7.80 KV 5.40 KNbTi 9.8 K
• Intemetallics (A15)Nb3Ge 23.2 KNb3Si 19 KNb3Sn 18.1 KNb3Al 18 KV3Si 17.1 KTa3Pb 17 KV3Ga 16.8 KNb3Ga 14.5 K
• “Unusual”Cs3C60 40 KMgB2 39 KBa0.6K0.4BiO3 30 KHoNi2B2C 7.5 KGdMo6Se8 5.6 KCoLa3 4.28 K
(Some) known superconducting materials
• Cuprates - Ln-SuperconductorsGdBa2Cu3O7 94 KYBa2Cu3O7-d 93 KY2Ba4Cu7O15 93 K
• Cuprates - Bi-SuperconductorsBi1.6Pb0.6Sr2Ca2Sb0.1Cu3Ox 115 KBi2Sr2Ca2Cu3O10 110 KBi2Sr2CaCu2O9 110 K
Low
Tc
High
Tc
Fusio
n an
d ac
cele
rato
rs, M
RI, S
MES
MRI
, SM
ES,C
able
s
Cabl
es, F
CL, r
otat
. mac
hine
s,SM
ES, M
RI
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Practical HTS conductorIngredients:• A continuous, textured, superconducting phase• Normal conducting metals for stability and protection• Mechanical reinforcementA complex composite material is needed in practice
extdHmT
Q 0AC loss
Limited (finite)current density J = Jc
Diffusion of magneticfield, ∂B/ ∂t
Electricfield, E
Power dissipationp = E∙J
A superconductor is not lossless if not operating in strict DC conditions
Further loss occurs in the normal conducting components of HTS composites
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YBCO coated conductors• Biaxial texturing is needed which can only be obtained by means of epitaxial growth
• AMSC (USA)
• D-Nano (D)
• Superpower (USA)
• Fujikura (J)
• SuperOx (Ru)
• Bruker (D)
• SuNam (Korea)
Less complex approach / less performing tapes
IBAD (Ion Beam Assisted Deposition)RABiTS (Rolling Assisted Bi-Axially Textured Substr.)
More complex approach / more performing tapes
• Complex technology & low yield - High cost, today (20-100 EUR/kA*m)
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Performance of practical Superconductors
Copper, intensive cooling
Copper, Air cooling
SuperpowerYBCO CC at 20 K
SuperpowerYBCO CC at 65KColumbus
MgB2 at 20K
SFCL, cables &transformersSFCL, cables &transformers
Motors& GeneratorsMotors& Generators
SMESSMES AdvancedmagnetsAdvancedmagnets
3.78 kW/dm3
0.15 kW/dm3
All superconductors have negligible losses comparedt o copper
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Market relevant Coated Conductor producers
Source: Bernhard Holzapfel – IndustrialCoated Conductor Production andProperties – EUCAS 2017 Geneva
Overall worldwide ever deliveredCC volume (4 mm equivalent) 3000 km
Expected delivered volume 2500 km/year in 20185000 km/year in 2020
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Cost estimate of practical Superconductors
Power transm. &distribution
High field rotat.machines
Storage & extrahigh field rotat. machines
Costs assumption:• 20 €/kA/m for HTS
CC @ 77K-s.f.• 2 k€/km for 3×0.5
mm2 MgB2 tape• 5 k€/ton for Copper
• Today cost of HTS CC @ 77K-s.f. is 100 €/kA/m
• Short term projected cost is 20 €/kA/m
Near-term cost ofconductor,EUR/kA/m
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• The state of the art of practical HTS materials
• Superconductor Technology for power systems• Fault current limiters
• Power Cables
• Energy Storage (SMES and Flywheels)
• Conclusion
Outline
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… fault happens !!!
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a poly-phase fault produces an overcurrent, which in turn produces:Effects of fault in power grid
Damage of components Outage or even black out
Voltage disturbance
The ultimate effect is an economic damage for both operators and customers
OUTAGESGREATER
THAN 100 MW
OUTAGESAFFECTING
50 000 +CUSTOMERS
IEEE Spectrum –Jan, 2011; S. Massoud Amin
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Low short circuit power
Normalcondition
Fault
• poor persistentvoltage quality
• high persistentvoltage quality
• low vulnerability• high transient
voltage quality
• high vulnerability• poor transient
voltage quality
loadscc
cc XV
S2
short circuitpower
For obtaining high network’s performance both during normal condition and fault,a condition-based increase of the impedance is required
Fault current limiter (FCL): a device with a negligibleimpedance in normal operation able to switch to ahigh impedance state in case of extra current (fault)
impe
danc
e
current
High short circuit power
Controlling the short circuit power
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Effect if the FCL – a case study
Standards EN61000-4-1 and EN61000-4-34 specify theresidual voltage VR on equipment during a disturbance
Both the peak current and the thermal let-through are greatly reduced
During fault residual voltage below the thresholdof even tolerant equipment at all buses
Current limiting behavior Voltage sag mitigation of healthy buses
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Resistive Type Superconducting Fault Current Limiter
M. Noe, EUCAS 2017 Short Course , Power Applications–Fault Current Limiters
non inductive SC coil
Advantages• Immediate and fail safe
operation• Compact size• Negligible impedance in
normal condition• High impedance gain• Excellent maturity
Critical aspects• Recovery time• AC operation of the SC - AC
loss• Hot spots during light
overcurrent• Direct exposure of the SC
component to high voltage
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Saturated Core Type Superconducting Fault Current Limiters
Advantages• Immediate and fail safe operation• DC operation of the
superconductor (no AC losses)• No direct exposure of the SC
component to high voltage• (Virtually) immediate recovery
Critical aspects• Low and narrow impedance gain• Non negligible impedance in
normal operation• Very large size• Losses in the copper coil• Overvoltage on the SC winding
during the fault and possibledemagnetization of the coreduring the fault
Half wave – single phase
Full wave – single phaseFull wave – three phases
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The state of the art of FCL
INNOPOWER2011BSCCO
RSE2011BSCCO
KEPRI2011YBCONEXANS
2009BSCCO Bulk
AMAT2016YBCO
SIEMENS2016YBCO ZENERGY
2012BSCCO
ASG2017MgB2
Complete demonstrators submitted to laboratory and/or field tests
NEXANS2009BSCCO Bulk
NEXANS2015YBCO
AMAT2013YBCO
NEXANS2009YBCO
INNOPOWER2009BSCCO
NEXANS2015/AMPACITYYBCO
KEPC2019YBCO
China, fundedproject2019 ?YBCO
DC FCLFAST GRID – EU2021YBCO
SUPEROX2019YBCO
China, funded project2019 ?YBCO
Volta
ge, k
V
Current, kA
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Some Achievements
Siemens Applied Materials
Resistive type, YBCO12 kV, 815 AInstalled 3/2016Augsburg, Germany
Resistive type, YBCO115 kV, 550 AInstalled 7/2016Thialand Saturated core type, YBCO
220 kV, 800 AInstalled 2012Tianjin, China
Innopower
M. Noe, EUCAS 2017 Short Course , Power Applications–Fault Current Limiters
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Rated voltage 36kV
Continuous normal current 800 Arms
Maximum normal current 1400A / 15 minutes
Unlimited peak fault current 20.9 kApeak / 7.8 kArms
Peak limited current 13.0 kApeak / 4.8 kArms
Fault duration Up to 3 seconds
Maximum allowable voltage drop 600V rms
A 36 kV / 800 A saturated core SFCL for real grid installation
Successfully tested at IPH in Berlin in October 2016• 5 faults with 200 ms duration• 1 fault with 3 s duration
To be installed in Substation for a 3 year trial
A range of SFCLs of similar design is available fromASG Power Systems for service at 75 kV and 145 kV
Developed by ASG Power Systems(formerly by Applied Supercond. )
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The smart coilAir core reactors are used for fault currentmitigation at the transmission (HV) level
- Effective protection of componentsduring the fault
- Permanent increase of the grid’stotal reactance - low gridperformance in normal conditions
Xcc
U
load
Xacr
air corereactor
VFCL
IFCL Copper winding
SC
Smart coil: SC shielded air core reactor
Normalcondition
Fault
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• The state of the art of practical HTS materials
• Superconductor Technology for power systems• Fault current limiters
• Power Cables
• Energy Storage (SMES and Flywheels)
• Conclusion
Outline
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J.-M. Saugrain (Nexans),IASS Workshop, May 13, 2011
Layout of a HTS power cables – cold dielectric
Schematic of a HTS power cable
• Suitable both for AC and DC operation
• Different layout, with dielectric operating at roomtemperature, exists
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Three phases arrangements
10 – 20 kV
30 – 100 kV
> 100 kV
Concentricphases
Separate phaseswith shared cryostat
Separate phasesand cryostat
voltage
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Cooling
Different cooling options, also using separate return lines for the coolant, existsdepending on the layout of the cable
10 kW cooling power at 77 K12 W input / W cold30000 hours maintenance
Heat load of power cable1-3 W/m/cryostat (radiation + AC loss)50 W/kA/termination
Cooling system is an integral part of the cable
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Advantages of HTS cables
• High current capacity & Highpower density
• Increased power at thesame voltage
• Reduced voltage at thesame power
• Reduced size
• Constant temperature operation• No derating at hot ambient
temperature• possibility of overload
• Fault current limiting capacity (ifproperly designed)
• Lower losses (cooling included)• Lower inductance
Flex
ible
plan
ning
F. Lesur, RTE, Superconducting MgB2 cable, Potsdam - 2013
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A case study in distribution: Upgrading city center with MV HTS cables
40 MVA2 km
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• Long Island Power Authority – HolbrookSubstation
• 600 m long cold dielectric cable system• 138kV/2400A ~ 574MVA• 51 kA @ 12 line cycles (200ms) fault current• 600 meter cable pulled in underground
HDPE conduit
The Long Island HV HTS power cable
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M. Noe
R&D status of HTS (AC) cables (as of 2013)
Complete 3-phase demonstrators submitted to laboratory and/or field tests
D712 SupercaboUFRRJ Brazil, 10 m2017, to be tested
Tennet, Enschede NL, 3.4km, 2019, proc. in porgress
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More on HTS (AC & DC) cables
Minwon Park, Changwon National University, Recent status and progress on the HTSapplication of AC and DC power transmission in Korea, Sep. 20 2017 EUCAS, GENEVA
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• The state of the art of practical HTS materials
• Superconductor Technology for power systems• Fault current limiters
• Power Cables
• Energy Storage (SMES and Flywheels)
• Conclusion
Outline
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Grid
Customer
The need for electric energy storageInherent generation / load imbalance due to loadsfluctuation and non programmable generation
Methods/technologies for grid energy management• Curtailment of renewables• Improved controllability of convent. generation• Demand control• Network upgrade ( … Supergrid )• Energy storage
Energy storage
• Power quality and UPS
• Leveling of impulsive/fluctuating power
(industry, physics, … )
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Which storage technology?
Parameters of the energy storage system• Absorbed/supplied power, P• Duration delivery, t• Number of cycles, N• Response time, tr
No unique storage technology exists able to span the wide range of characteristicsrequired for applications
• Most suitable storage technology mustbe chosen from case to case
• Hybrid systems, obtained by combiningdifferent storage technologies,represent the best solution in manycases
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• High deliverable power• Virtually infinite number of cycles• High round trip efficiency• Fast response (<1ms) from stand-by to full
power• No safety hazard
• Low storage capacity• Need for auxiliary (cooling) power• Idling losses
SMES is an option for• Fast delivery of large power for short time
UPS for sensitive industry customers, bridging power, pulsed load (physics), ….
• Short term increase of peak power of energy intensive systemsin combination with batteries, hydrogen, liquid air, ….
• Continuous deep charge/discharge cyclingleveling of impulsive loads
Superconducting Magnetic Energy Storage - SMES
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Power conditioning system – control hardware and algorithms
System level controlP*, Q*, v*
• Power is transferred from the DC bus to thegrid by means of the inverter
• Voltage of the DC bus kept constant by theSMES by means of the two quadrant chopper
• Magnet protection system integrated in thePCS both at hardware and the software level
An open issue: minimization ofstand-by loss
• SiC technology• Multilevel structure with
MOSFET• Cryogenic power electronics
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Japan
Germany
EM Laucher
JapanUSA
Japan
Italy
France
GermanyPower modulatorFlicker
Gridcompensation
The state of the art of SMES technology
The DRYSMES4GRID project:• 500 kJ / 200 kW SMES• MgB2 material• Cryogen free cooling
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The Kameyama SMES
10 MW – 1 s SMES system
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• Transmission and distribution• Dispersed generation, active networks and storage• Renewables (PV and Biomass )• Energy efficiency in the civil, industry and tertiary sectors• Exploitation of Solar and ambient heat for air conditioning
MISE - Italian Ministry of Economic DevelopmentCompetitive call: research project for electric power grid
The DRYSMES4GRID Project
Partners• University of Bologna• ICAS - The Italian Consortium for ASC, Frascati (Rome)• RSE S.p.A - Ricerca sul Sistema Energetico, Milan• CNR – SPIN, Genoa
Project DRYSMES4GRID funded
• Budget: 2.7 M€• Time: June 2017 – June 2020
Project Coordinator:• Columbus Superconductors SpA, Genova, Italy
• developm. of dry-cooled SMES based on MgB2• 300 kJ – 100 kW / full system
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Project Workplan
WP2. Layout and functionsWP3. Detailed design and manufact. of converters
Power conditioning system
WP1. Electromagnetic & thermal design
Design of the magnet
WP4. Optimization of in-field perform. of the wireWP5. Manufacturing of wire, cable and winding
Wire, cable and winding
WP6. Assembly of coil and cooling & prelim. testWP7. Assembly of PCS & Experiments in test facility
Assembling and test
WP8
. Diss
emin
atio
n
WP9
. Pro
ject
man
agem
ent
WP1
0.Te
ch.&
Econ
.ana
lys.
of S
MES+ PE industry
+ 6 months
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RSE DER (Distributed Energy Resources) Test FacilityA real low voltage microgrid that interconnects different generators, storage systemsand loads to develop studies and experimentations on DERs and Smart Grid solutions.
20000 m2 areaSupplied by MV Grid800 kVA - 23 kV/400 V transf.
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Superconducting levitation - flywheels and maglev
Inherently stable levitation is obtained betweenpermanent magnets and HTS bulks allowing obtainingpassive (fail-safe) axial and linear bearings
linear bearingaxial bearing
Babcock Noell GmbH –Cristian BoffoESAS Summer School2016 – Bologna
Superconducting flywheel Superconducting MAGLEV
• 1.5-m-long wagons• 200 meters test line
Maglev-Cobra, UFRJ 2014
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3 5 10 100Energy, kWh
0
50
100
150
200
250
300
Pow
er,k
W
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2009
2016
2015
R&D status of HTS flywheel
300 KW / 100 kWh6000 rpmrotating mass 4 ton
250 KW / 5kWh10000 rpmrotating mass 600 kg
3 KW / 5 kWh14500 rpmrotating mass 132 kg
2009
250 KW / 3 kWh20000 rpmrotating mass 225 kg
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Conclusion 1/3• Annual yield of robust high performance
superconductors is steadily increasing3000 km before 20182500 km/year in 20185000 km/year in 2020
• Today cost is 100 EUR/kA/m (s.f, 77K). Cost reduction below 20 EUR/kA/m(threshold for market penetration) can be expected in the short term due toscale economy
Power Cables
SFCLsSMES
Flywheels
• First commercial HTS power cables and fault current limiters productsalready exists
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Conclusion 2/3…. but superconductors rely on cooling. Is cooling technology well established,available and reliable enough?
10 kW cooling power at 77 K12 W input / W cold30000 hours maintenance
Up to 50 kW cooling power at 77 K12 W input / W cold30000 hours maintenance
Enough for the cooling of km long cables or High Voltage Fault Current Limiters
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Easter morning, 1900, New York City, 5th AvenueSpot the automobile
Easter morning, 1913, New York City, 5th AvenueSpot the horse
Conclusion 3/3
…. change happens, quickly!