Comparison of High Power Non-Isolated Multilevel DC-DC ...
Transcript of Comparison of High Power Non-Isolated Multilevel DC-DC ...
Laboratory for High Power Electronic Systems
Comparison of High Power Non-Isolated Multilevel DC-DCConverters for Medium-Voltage Battery Storage Applications
Optimization Results
Abstract
Module Design & ConclusionOptimal Design of 4L-FC for Nominal Load
Multi-Level Converter Topologies
sccermobilitySwiss Competence Center for Energy ResearchEfficient Technologies and Systems for Mobility
High currents flowing through capacitors C1 and C2.
VC1 > Vin for proper operation.
Diodes DC1− DC6 are low current devices used forclamping only.
Two level operation identical to basic buck-boostoperation.
Milos Stojadinovic, Jürgen BielaLaboratory for High Power Electronic SystemsPhysikstrasse 38092 Zürich, [email protected]
Frequency multiplication of the inductor current ripple(i.e. lower inductance compared to NPC topology).
In this paper 4-level neutral-point-clamped (4L-NPC), 4-level flying-capacitor (4L-FC) and 4-level neutral-point clamped Cuk (4L-NPC-Cuk) converter topologies for multilevel DC-DC buck-boost converter for medium-voltage battery storage applications are compared with respect to effi-ciency and power density. The comprehensive comparison is performed with multi domain models and optimization procedures. For the converters, pareto-fronts are calculated for differ-ent operating frequencies in order to find the optimal design with respect to the specifiedminimum efficiency.
Optimal Inductor Design for the 4L-FC Circuit. Resulting System with 8 Interleaved Modules.
Core Material METGLAS2605SA1115 µH95.000 x 0.36 mm 1.8 A/mm2
357 W
InductanceNumber of TurnsHF Litz WireCurrent DensityTotal Losses
75 KTemperature Rise25 °CAmbient Temperature
Battery Voltage Vin 530 ... 890 V2800 V4 MW
DC Link Voltage Vout
System PowerEfficiency > 95 %
Specifications
Core
Capacitor BankSemiconductors
Heat Sink
Gate Driver /Control Board
Winding
+-
L
S1
S2
S4
S3
C1C2
S5
S6
Vin
C3D1
D2
D4
D3
D5
D6
RVC1VC2 Vout
L
S1
S2
S4
S3
C1
S5
S6
D1
D2
D4
D3
D5
D6
Vin
VR
L
S1
S2
S4
S3
C1 C2
S5
S6
C3
D1
D2
D4
D3
D5
D6
+-
· · ·
· · ·
· · ·
· · ·
out
BidirectionalDC-DC
Converter
Battery Storage
AC-DCMultilevelRectifier
Wind TurbineMVDC
DC-DCConverter
PV Plant
DC-ACMultilevel
Inverter
Utility
4 MW
438 dm3
9.13 kW/dm3
Power (8 Modules Interleaved)
VolumePower Density
45 °CAmbient Temperature
97.4 %Maximum Efficiency
25 °CCooling Water Temperature
500 kWModule Power5000 HzFrequency
LFCLNPC
13= 2Vin
Vout - Vin(. 1 - )
+-
Auxiliary diodes
L
S1
S2
S4
S3
S5
S6
Vin
D1
D2
D4
D3
D5
D6
R Vout
DC1
DC2
DC3
DC4
DC5
DC6
C1
C2
C3
Heat Sink
IGBT M
odules
Capacitor Bank
Inductor Volume
160
140
120
100
80
60
40
20
0
Volu
me
[dm
³]
Heat Sink
IGBT M
odules
Capacitor Bank
Inductor Volume
Heat Sink
IGBT M
odules
Capacitor Bank
Inductor Volume
fS = 6kHzL = 1.38mH
fS = 6kHz fS = 5kHzL = 108µH
139.5
0.9 4.2 3
25.4
9.74.2 3
16.88.4 4.2 3
4L NPC CUK4L NPC 4L FC
Component volume comparison.
Example circuit schematic of the modular systemwith 4L-FC topology (8 interleaved modules).
Specification of the ParametersVin / Vout / Pout / Dmax
TT,max / Tcore,max / TA / Rth,IGBT
Electrical Model of the ConverterCurrents / Voltages / Flux Density
Initial ValueSwitching Frequency fsw
Winding & Core Lossesin the Inductor
as Function of Geometry
Minimization of Ind. LossesConstraints: BBmax
VolVolmax // JJmax
Losses in Semiconductors
Heat SinkScaling : RthRth,max
Global Optimization AlgorithmMinimization of Losses and Volume of the System
Optimal Design
Modification of the Values
InnerOptimization
Loop
Inductor Thermal ModelT<Tmax
Mod
ifica
tion
of th
e Va
lues
Optimization procedure with an inner loop for inductoroptimization.
0 2 4 6 8 10 12 14 16 1894.5
95
95.5
96
96.5
97
97.5
98
98.5
Power Density [kW/dm3]
Syst
em E
ffic
ienc
y [%
]
3kHz
4kHz
5kHz
2kHz270mH
3kHz180mH
4kHz135mH
5kHz108mH
2kHz4.14mH
3kHz2.76mH
4kHz2.07mH5kHz1.66mH
6kHz1.38mH
1000Hz6.2mH
Buck-Boost
4L-NPC
4L-FC4L-NPC-Cuk
6kHz
Pareto-fronts.
2800V, 500kWTamb=45ºC, Twater=25ºC
1400V, 25kWTamb=45ºC, Twater=25ºC
2800V, 100kWTamb=45ºC, Twater=25ºC
1400V, 100kWTamb=45ºC, Twater=25ºC
1400V, 500kWTamb=45ºC, Twater=25ºC
10 11 12 13 14 15 16 17 18 1994.5
95
95.5
96
96.5
97
97.5
98
Power Density [kW/dm 3]
Syst
em E
ffic
ienc
y [%
]
2800V, 25kWTamb=45ºC, Twater=25ºC
6 8 10 12 14 16 18
3kHz191mH
4kHz143mH
5kHz115mH
500Hz1.15mH 1kHz
574mH 1.5kHz382mH 2kHz
287mH2.5kHz230mH
Power Density [kW/dm3]
Syst
em E
ffic
ienc
y [%
]
5kHz, 115mHSwitching Losses 1/2nTamb=Twater=60ºC
2.5kHz, 230mHConvection Coef. 2nTamb=Twater=60ºC
2.5kHz, 230mHCore Losses 1/2nTamb=Twater=60ºC
2.5kHz, 230mHThermal Conductivityof Winding Isolation 2nTamb=Twater=60ºC
2.5kHz, 230mHThermal Conductivityof Core Material 2nTamb=Twater=60ºC
No ModificationsTamb=Twater=60ºC
Ambient and Water Temp.Tamb=45ºC, Twater=25ºC
4kHz, 143mHConduction Losses 1/2nTamb=Twater=60ºC
94.5
95
95.5
96
96.5
97
97.5
98
98.5
System pareto-fronts for the 4L-FC converter withscaled operating points.
Pareto front with the added points resulting from thetechnology value modifications for the 4L-FC converter
+-
C1
Auxiliary diodes
L1
S1
S2
S4
S3
S5
S6
Vin
D1
D2
D4
D3
D5
D6
RVout
DC1
DC2
DC3
DC4
DC5
DC6
L2
C2
C3
C4
C5
Reduced inductor size due to coupling compared toregular NPC topology.
Current ripple reduction sensitive to magneticcomponent parameter change.
Larger volume of the capacitor bank compared toregular NPC topology.
Heat Transfer Coefficient 2x increase2x increase2x increase2x decrease
2x decreaseT=60 °C → 45 °C
Thermal Conductivity of Core MaterialThermal Conductivity of WindingCore Losses
Semiconductor Switching LossesTemperature of the Ambientand Cooling Water
2x decreaseSemiconductor Conduction Losses
T=60 °C → 25 °C
Modified Technologies for the Sensitivity Analysis.
77 cm
79 cm
72 cm
12.8 cm
25.7 cm
35.6
cm
4-Level Neutral-Point Clamped Topology (4L-NPC) 4-Level Neutral Point Clamped Cuk Topology (4L-NPC Cuk) 4-Level Flying-Capacitor Topology (4L-FC)
Simplified Mechanical Drawing of a Single Moduleof the 4L-FC Interleaved System
In this paper, 4L-NPC, 4L-FC and 4L-NPC-Cuk converters are evaluated with respect to power density and efficiency for medium-voltage battery storage applications.
4L-FC topology results in the most compact system.
From the sensitivity analysis, biggest increase of the power density is achieved by investing in a better colling system and more efficient switching compo-nents.
From the scalability analysis, further volume reduc-tions can be achieved by properly selecting the module power level.
System Design
Sensitivity Analysis Scalability AnalysisResults for Nominal ConditionsOptimization Algorithm
Semiconductors
METGLAS2605SA1Cornell Dubilier 944U
AavFin Liquid Cold Plates
CapacitorsCore MaterialHeat Sink
Infineon FZ1600R17HP4Components
Output Power 4 MW530 V2800 V
Input VoltageOutput Voltage
Nominal Conditions
Sensitivity Analysis: Modification of the technology values and the influence it has on power density of the system.
Scalability Analysis: Reduction in the module power and output voltage values and the influence it has on power density of the system.