07/11/2014 1 Direct Current Distribution Network an opportunity for a distribution system operator? Hans Schneider, Liander Frans Provoost , Liandon European Utility Week 2014, Amsterdam, November 5 th 2014 Outline Context 1. DSO Liander – company profile 2. Local sustainable energy supply with a Direct Current Grid? 3. Direct Current, WHY? Case 4. Feasibility study 5. Some design issues 6. Preliminary conclusions 7. The road ahead
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07/11/2014
1
Direct Current Distribution Network an opportunity for a distribution system operator?
Hans Schneider, Liander Frans Provoost , Liandon
European Utility Week 2014, Amsterdam, November 5th 2014
Outline
Context
1. DSO Liander – company profile
2. Local sustainable energy supply with a Direct Current Grid?
3. Direct Current, WHY?
Case
4. Feasibility study
5. Some design issues
6. Preliminary conclusions
7. The road ahead
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2
DSO
electricity
& natural
gas
DSO
electricity
& natural
gas
Engineering,
projects,
consultancy
Liander: Distribution System Operator.
Member of the Alliander Group
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3
6
Sustainable energy for a new business park near Lelystad Airport…
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Will a DC-grid add value
to local green energy solutions?
7
Main actors:
• Lelystad Airport – the fast-growing daughter of Schiphol
Airport
• OMALA – the ambitious area developer
• Liander – the cautious grid company
The common objective:
• Investigate whether a (public) DC-grid connecting solar &
wind supply with local DC demand is a feasible
undertaking.
Some artist impressions
8
Leisure dome
Fast-charging
filling station
Solar-parking
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A DC-grid?
Why for heaven’s sake?!
Direct current applications are everywhere
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Should Liander consider a DC-grid?
NO! Too many challenges for DC:
• No standards
• No certified metering
• No maintenance & safety protocols
• Legal fuzziness
• No economy of scale – components far too expensive
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Should Liander consider a DC-grid?
YES! Interesting claims for DC:
• Lower standby and conversion losses
• No reactive power
• Lower distribution losses
• Longer technical lifetime of components
• Active & passive safety
• Reliability:
- More redundancy in converters & feed-in locations
- Possibility to keep outage areas very small in case of
cable damage or sabotage.
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DSO (AC)
~ = ~ = ~ = ~ =
Customers
DC AC DC AC DC AC DC AC
Regular AC-grid
AC-DC conversion on client’s site
DSO (AC + DC)
Customers
DC AC DC AC DC AC DC AC
~ =
Mixed AC & DC-grid
AC-DC conversion by DSO
Partial balancing within DC-grid possible
Fewer converters needed
Can DC create smarter grid designs?
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How? The feasibility study
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A long list of demands, risks & issues
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• Safety
• Reliability
• Redundancy & back up
• Failure detection
• Maintenance & repair
• Metering
• Voltages
• Design issues
• Cables
• Converters
• Power Quality
• Power management
• Pricing
• Freedom of choice for all
clients in the area?
• Free energy supplier
access?
• And so on…
Feasibility study
Co-creation process with three main stakeholders:
• Area developer OMALA
• Lelystad Airport
• DSO Liander
Feasibility study with 3 main themes:
• Business case
• Technical issues
• Legal & regulatory issues
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How? Some grid design issues
Potential clients at the business park Projected power demand & supply
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2.930 kW
(200 DC
-3.130 DC)
1.130 kW
(500 AC
630 DC)
2.350 kW
(-2.350 DC)
225 kW
(225 DC)
Eventueel V2G
500 kW
(-500 DC)
1.130 kW
(500 AC
630 DC)
Solar
Parking
Hotel
LED-lichting
Leisure dome Long stay
EV Parking
DC-power for
aircrafts
LED lighting
platform
Te
rmin
al
Large solar
plant
LED lighting
landing strip
Small wind
farm Multi fuel
filling station
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Three grid design scenarios
1. Reference scenario
Regular AC grid for all clients
Regular DC-AC conversion at the client’s site
2. Full DC-grid
with DC-AC conversion for AC clients
3. Mixed AC-DC grid
Regular AC-grid for AC-clients
DC-grid for DC-clients
(with conversion to AC-grid by DSO)
Scenario 1: Reference AC-grid
MS-rail substation MS-rail substation
PV solar field Wind farm Solar Parking
Feeder A
Feeder B
Offices Leisure
dome
Airport
Parking Airport Hotel
Multi-fuel
station
LED
lighting
Regular AC-grid with two connections to substation for high power PV-installations
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Separate
connection to
substation
Low Voltage Alternating Current (LV - AC)
Medium Voltage Alternating Current (MV-AC)
Separate
connection to
substation
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Scenario 2: Full DC-grid
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Feeder A Feeder B
Low Voltage Alternating Current (LV-AC)
Medium Voltage Alternating Current (MV-AC)
Low Voltage Direct Current (LC-DC)
Medium Voltage Direct Current (MV-DC)
PV solar field Wind farm Solar Parking
Offices
Leisure
dome
Airport
Parking Airport
Hotel Multi-fuel
station
LED
lighting
Scenario 3: Mixed AC-DC grid (1/2)
DC-grid
connecting wind
Feeder B Feeder A
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OMALA AC/DC station
Synergy due to short distances
AC
DC
DC DC+
AC AC
PV solar field Airport
Low Voltage Alternating Current (LV-AC)
Medium Voltage Alternating Current (MV-AC)
Low Voltage Direct Current (LC-DC)
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(Clustering load and generation around Solar Parking)
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Offices Leisure
dome
Hotel
DC zon
-880 kW
AC
DC
AC
320 kW
465 A AC
80 kW
120 A
AC
100 kW
140 A
DC
315 kW
450 A
DC
170 kW
240 A
DC
100 kW
140 A
DC
2 kW
3 A
DC
50 kW
70 A
DC
225 kW
320 A
DC zon
-780 kW
DC zon
-780 kW
DC zon
-680 kW
600 kW 600 kW 600 kW 600 kW
LV DC
LV AC
MV AC Trafo
2.000 kVA
Converters
2.000 kW
280 A
DC load
200 kW
OMALA AC
Max load : 1.550 kW
Max Gen : 1.880 kW
Trafo
1.000 kVA
Trafo
1.000 kVA Trafo
1.000 kVA
OMALA DC
Max load : 1.050 kW
Max Gen : 2.280 kW
Scenario 3: Mixed AC –DC grid (2/2)
Solar Parking
Airport
Parking
Multi-fuel
station
LED
lighting
Solar Parking Solar Parking Solar Parking
Transformers and power converters
needed in each scenario
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Component Unit
Scenario 1
Regular
AC-grid
Scenario 2
Full
DC-Grid
Scenario 3
Mixed
AC/DC-
grid
Transformers
(MV/LV)
kVA 7.650 0 4.850
Total
converter
power
kW 7.450 12.020 5.100
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Preliminary conclusions
Technical issues
• No real show stoppers
• Interesting unforeseen design opportunities
- smart combinations of supply & demand within the DC-grid lead to smaller
client-grid-connections
- partially due to design restrictions in (regulated) AC-grid
- shorter overall (MV) cabling
• A lot of practical implementation issues:
- training of technical personnel,
- maintenance,
- quality assurance,
- safety
• Low availability of proven power electronic devices
• DC metering not yet available as a certified service
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Business case
• No positive business case in the short term
• Split incentive:
- advantages for clients;
- cost & risks for DSO
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Legal & regulatory issues
• DC-meters not yet certified and require law adjustments.
• A DC-grid is currently not identified as a public service of
the DSO under Dutch law.
• Are DC- and AC-grids not both ‘natural monopolies’ which
should be a public service of the DSO?
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The road ahead
The road ahead for DC-grids
in the Netherlands
1. The long and winding road of discussion on policies,
law adjustments and business rules...
2. Learning by doing and/or more R&D
3. An open eye for specific niches & game changers: