Power Density vs. Efficiency of Power Electronics · Advanced Cooling Concepts Schedule 09/2004...
Transcript of Power Density vs. Efficiency of Power Electronics · Advanced Cooling Concepts Schedule 09/2004...
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Power Density vs. Efficiency of Power Electronics
Johann W. Kolar
Swiss Federal Institute of Technology (ETH) Zurich Power Electronic Systems Laboratory
www.pes.ee.ethz.ch
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► How It All Began ► Recognizing Power Density Barriers ► Multi-Objective Optimization ► Application Examples ► Generalization ► Conclusions
Outline
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How It All Began…
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1. ECPE Demonstrator Program Max. Power Density
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Demonstrator Program
Development of Ultra Compact Three-Phase Power Supplies
for
by ETH Zurich
Power Electronic Systems Laboratory
ETH Zentrum, ETL H22 Physikstrasse 3 CH-8044 Zurich
Note: 2004 !
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Demonstrator Program
2004 – 2006 Projects 1 - 3
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Roadmap of the PERC (Power Electronics Research Center), Japan, coordinated by the National Institute of Advanced Science and Technology
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System Aspects Multi-Chip Power Module Discrete Passive Components
IPEM Gate Drive Integration Current Sensor Integration Integrated Passives Planar Interconnections Novel Semicond. Techn. Advanced Cooling Concepts
09/2004 03/2005 12/2005 12/2006
10kW/l
20kW/l
50kW/l
System Aspects Thermal Integration EMI Filter Integration
!
Projects 1 - 3
25 GHz.W
Demonstrator Program 3~ AC/DC Power Supplies
Schedule
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Basic Project Objective Development of Ultra Compact Three-Phase AC/DC Utility Interfaces
Application Areas
■ Variable Speed AC Drives ■ IT Systems ■ Process Technology
Focus ■ Application of Advanced Power Semiconductor Technology (SiC) ■ Integration, and Advanced Cooling Techniques ■ 50kW/l ■ Efficiency, Power Density/Size ■ Consideration of Reliability, EMI Standards and Costs Reduction
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Project 1 Power Supply with 10kW/l Power Density
Tasks / Efforts
■ Evaluation of Circuit Topologies
■ Electronic Inductor Topology ■ Unity Power Factor Three-Phase PMW Rectifier
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3-Ф Unity Power Factor PMW Rectifier
New Technologies
COOLMOS / SiC-Diodes Micro-Channel Heat Sink High-Speed DSP-Control Flat Magnetics HBW & CMR Current Sensing
PO = 10 kW UN = 3-F 480VAC UDC = 800 VDC fS = 500 kHz
10 kW/dm3 10 kW/dm3 10 kW/dm3
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10 kW/dm3 3-Ф Unity Power Factor PMW Rectifier PO = 10 kW UN = 3-F 480VAC UDC = 800 VDC fS = 500 kHz
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EMC Input Filter
Electrolytic Capacitors
N 30%
30%
N 30% Power Circuit / Cooling
Partitioning of the Converter Volume
Main Share of Passive Components
10 kW/dm3
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“Red Brick Walls” in Power Electronics
J.W. Kolar, U. Drofenik, J. Biela, M.L. Heldwein, H. Ertl, T. Friedli and S.D. Round
Swiss Federal Institute of Technology (ETH) Zurich Power Electronic Systems Laboratory
www.pes.ee.ethz.ch
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0.01
0.1
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10
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1000
1970 1980 1990 2000 2010 2020 2030
[5]
[43]
[17]
[15][11]
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[7]
[13]
[10]
Year
Po
wer
den
sity
[k
W/d
m3]
[16]
3-phase AC-DC
Isolated DC-DC
1-phase AC-DC
3-phase AC-AC
Power Density Roadmap
“ Red Brick Walls “ in Power Electronics
[10] Dr. Ohashi, 2002/2006 ■ Requires Separate Consideration of Basic Converter Types
* AC/DC * DC/DC * DC/AC * AC/AC ■ Requires Definition of Cooling Concept
* Natural Convection * Forced Air Cooling * Water Cooling ■ Consider Systems NOT Modules
►
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Forced Convection Cooling Power Density Limit
► Ts = 90°C ρlim = 29 kW/dm3
► Ts = 135°C ρlim = 58 kW/dm3
CS
Olim
Vol
P
iO PP
CSPIT
P
CSPI
GVol
as
LossthCS
1
]dm
W[
13
CSPIT as
iLoss PP )1(
Ta = 45°C, CSPI = 20 WK-1dm-3
@ η = 97%
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Forced Convection Cooling Power Density Limit
► Ts = 90°C ρlim = 29 kW/dm3
► Ts = 135°C ρlim = 58 kW/dm3
CS
Olim
Vol
P
iO PP
]dm
W[
13
CSPIT as
iLoss PP )1(
Ta = 45°C, CSPI = 20 WK-1dm-3
@ η = 97%
Coupling of
Efficiency & Power Density
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2. ECPE Roadmap Initiative Power Density
Efficiency Costs etc.
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Note: 2007 !
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3. Efficiency (!) “THE” New Target
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► Requirements (1) Efficiency (2) Power Density (3) Costs
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4. Time to Come Up with a Theoretical Foundation Multi-Objective Optimization
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Power Electronics Performance Trends
─ Power Density [kW/dm3] ─ Power per Unit Weight [kW/kg] ─ Relative Costs [kW/$] ─ Relative Losses [%] ─ Failure Rate [h-1]
■ Performance Indices
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► Mapping of Design Space into System Performance Space
Abstraction of Power Converter Design
Performance Space
Design Space
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Mathematical Modeling and Optimization of Converter Design
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Multi-Objective Converter Design Optimization
► Pareto Front - Limit of Feasible Performance Space
►
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► Sensitivity to Technology Advancements ► Trade-off Analysis
Technology Sensitivity Analysis Based on η-ρ-Pareto Front
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Converter Performance Evaluation Based on η-ρ-σ-Pareto Surface
► σ: kW/$
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Converter Performance Evaluation Based on η-ρ-σ-Pareto Surface
► ´ Technology Node´
►
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Demonstrator Systems 3-ph. VIENNA Rectifier
1-ph. PFC Rectifiers Inductive Charging Power Supply on Chip
Airborne Wind Turbine
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● Specifications ULL = 3 x 400 V fN = 50 Hz … 60 Hz or 360 Hz … 800 Hz Po = 10 kW Uo = 2 x 400 V
fs = 250 kHz ● Characteristics η = 96.8 % THDi = 1.6 % @ 800 Hz 10 kW/dm3 3.3 kg (≈3 kW/kg)
Dimensions: 195 x 120 x 42.7 mm3
► Demonstrator – VR250 (1)
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Dimensions: 195 x 120 x 42.7 mm3
► Demonstrator – VR250 (2)
● Specifications ULL = 3 x 400 V fN = 50 Hz … 60 Hz or 360 Hz … 800 Hz Po = 10 kW Uo = 2 x 400 V
fs = 250 kHz ● Characteristics η = 96.8 % THDi = 1.6 % @ 800 Hz 10 kW/dm3 3.3 kg (≈3 kW/kg)
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10A/Div
200V/Div 0.5ms/Div
PO = 10kW UN = 230V fN = 400Hz UO = 800V THDi = 1.4%
10A/Div
200V/Div 1ms/Div
PO = 10kW UN = 230V fN = 800Hz UO = 800V THDi = 1.6%
► Mains Behavior @ fN = 400Hz / 800Hz
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■ Generation 1 – 4 of VIENNA Rectifier Systems fs = 50 kHz ρ = 3 kW/dm3
fs = 72 kHz ρ = 4.6 kW/dm3
fs = 250 kHz ρ = 10 kW/dm3
(164 W/in3) Weight = 3.4 kg
fs = 1 MHz ρ = 14.1 kW/dm3
Weight = 1.1 kg
● Switching Frequency of fs = 250 kHz Offers Good Compromise Concerning Power Density / Weight per Unit Power, Efficiency and Input Current Quality THDi
► Experimental Analysis
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■ Generation 1 – 4 of VIENNA Rectifier Systems fs = 50 kHz ρ = 3 kW/dm3
fs = 72 kHz ρ = 4.6 kW/dm3
fs = 250 kHz ρ = 10 kW/dm3
(164 W/in3) Weight = 3.4 kg
fs = 1 MHz ρ = 14.1 kW/dm3
Weight = 1.1 kg
● Switching Frequency of fs = 250 kHz Offers Good Compromise Concerning Power Density / Weight per Unit Power, Efficiency and Input Current Quality THDi
► Experimental Analysis
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► Si CoolMOS, 99mΩ/600V ► SiC Diodes, 10A/600V
PO=3.2kW UN=230V±10% UO=365V fP=33kHz ±3kHz Two Interleaved 1.6kW Systems
99.2% @ 1.1kW/dm3
1-Ф Boost-Type PFC Rectifier
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Ultra-Efficient PFC Rectifier Performance Limits
─ Inductor ─ Output Cap. ─ Heatsink
─ Output Diodes ─ Power MOSFETs ─ Aux. Power
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Experimental Ultra-Compact 1-Ф PFC Rectifier
PO=3.2kW UN=230V±10% UO=400V fP=450kHz ±50kHz Two Interleaved 1.6kW Systems
5.5kW/dm3
► Si CoolMOS ► SiC Diodes
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Feasible Performance Space
► Bridgeless PFC Rectifiers @ uN = 230V
Power Density is Based on Net Volumes Scaling by 0.6-0.8 Necessary
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► Employs NO SiC Power Semiconductors -- Si SJ MOSFETs only
Bidirectional Ultra-Efficient 1-Ф PFC Mains Interface
99.36% @ 1.2kW/dm3
Hardware Testing to be finalized in September 2011
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No Soft-Switching Soft-Switching with Extended On-Interval of S11
AC-DC Rectifier - Single Boost Cell - Measurements
Vo
ltag
e (
V)
Cu
rren
t (
A)
Vo
ltag
e (
V)
Cu
rre
nt
(A
)
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Bidirectional Ultra-Efficient 1-Ф PFC Mains Interface
99.36% @ 1.2kW/dm3
► Employs NO SiC Power Semiconductors -- Si SJ MOSFETs only
Hardware Testing to be finalized in September 2011
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99.36% @ 1.2kW/dm3
► Employs NO SiC Power Semiconductors -- Si SJ MOSFETs only
Result of Final Testing
Results of first testing; System still to be optimized further
Target
Bidirectional Ultra-Efficient 1-Ф PFC Mains Interface
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Converter Performance Evaluation Based on η-ρ-Pareto Front
►
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“Out-of-the-Box” Wind Turbine Concepts Power Kite & Ground-Based EE-Generation
Power Kite & On-Board EE-Generation
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Revolutionize Wind Power Generation Using Kites / Tethered Airfoils
■ Wing Tips / Highest Speed Regions are the Main Power Generating Parts of a Wind Turbine
[2] M. Loyd, 1980
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Controlled Power Kites for Capturing Wind Power
■ Wing Tips / Highest Speed Regions are the Main Power Generating Parts of a Wind Turbine
► Replace Blades by Power Kites ► Minimum Base Foundation etc. Required ► Operative Height Adjustable to Wind Conditions [2] M. Loyd, 1980
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Alternative Concept – Airborne Wind Turbine (AWT)
► Power Kite Equipped with Turbine / Generator / Power Electronics ► Power Transmitted to Ground Electrically
Source:
[2] M. Loyd, 1980
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AWT Basic Electrical System Structure
► Rated Power 100kW ► Operating Height 800…1000m ► Ambient Temp. 40°C ► Power Flow Motor & Generator
■ El. System Target Weight 100kg ■ Efficiency (incl. Tether) 90% ■ Turbine /Motor 2000/3000rpm
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Overall AWT System Performance
■ Final Step: System Control Consideration
►
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ηα-Pareto Front for Inductive Charging of EVs
* Pout = 0 … 75kW * Uout = 400 … 800V * Air Gap = 100 … 200mm
■ Reduction of Stray Field Results only Possible with Less Efficient Design
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ηα-Pareto Front of Inductor for Power Supply on Chip
* Uin = 1.6 V * Uout = 0.8 V * Pout = 1.0 W
- PCB - On-Top-of-Chip - On-Chip
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Observation
► Very Limited Room for Further Performance Improvement !
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Efficiency Power Density
Observation
► Very Limited Room for Further Performance Improvement !
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General Trade-Off Analysis Reliability vs. Efficiency
Costs vs. Efficiency
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Solid-State Transformer
DCM Series Resonant DC/DC Converter
(1) Transformer (2) LV Semiconductors (3) MV Semiconductors (4) DC Link (5) Resonant Capacitors
► Trade-Off Efficiency / Power Density
SN = 630kVA ULV = 400 V UMV = 10kV
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(5 Cascaded H-Bridges, 1700V IGBTs, No Redundancy, FIT-Rate calculated acc. to Tj, 100FIT Base)
► Trade-Off Mean-Time-to-Failure vs. Efficiency / Power Density
Solid-State Transformer
SN = 630kVA ULV = 400 V UMV = 10kV
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3-ph. PV Inverter Systems Si vs. SiC
UN = 400 V UPV = 450 … 820V P = 10kW fS = 4…16kHz
► Cost Models Efficiency / Power Density Analysis Extended to Initial Costs & Operating Revenue Calculation
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Conclusions Outlook
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► Only the Consideration of the “TECHNOLOGY NODE” – (η,ρ,σ)-Coordinates in the Performance Space Shows the Quality of a Design ! ► Don´t be Impressed by 99% Efficiency ► Don´t be Impressed by 100kW/dm3 Power Density ► Don´t be Impressed by 0.05kW/$ Rel. Costs ► Ask in Addition * Converter Type * Power Range / Operating Range * Type of Cooling * Technologies Used (SiC ?) * etc. ► There is Nothing Magic in Converter Design
►“Good Engineering & Multi-Objective Optimization”
Conclusions
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Thank You !
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Questions ?