Cryogenic Efficiency

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Cryogenic Efficiency

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Cryogenic Efficiency & Losses in AC Power Machines Dr. Philip Sargent MIM MBCS CDipAF CEng. Diboride Conductors Ltd. Power Superconductors Power Superconductors Cost ... – PowerPoint PPT presentation

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Title: Cryogenic Efficiency

1
Cryogenic Efficiency Losses in AC Power Machines

Dr. Philip Sargent MIM MBCS CDipAF CEng.
Diboride Conductors Ltd.

2
Power Superconductors
3
Power Superconductors
4
Cost of Capital when the superconductor is
costly
Lower capital costs, Expensive capital
Lower running costs, Cheap capital, Cheap
superconductor
5
Constraint Liquid Cryogens
Optimal Range
LOX!
6
Engineering Needs

Generators, Transformers, Cables, FCLs, Motors,
Grid conditioning, power storage
Capital cost is most important for all of these
in deregulated power markets
Why superconductors?
Higher power density, 100x the current
Smaller
Lighter (MgB2 is 1/3 the density of Copper)
Cheaper to buy and install
Cheaper to operate
Entirely new capabilities (FCLs)

7
HyperTech CTFF for MgB2
CONTINUOUS TUBE FORMING AND FILLING (CTFF)
8
Boron Chemistry

Pyrometallurgy Mg B heat
Powder in tube in situ
Powder in tube ex situ
Powder in tube ex situ Mg
Powder in tube HIP
CVD Mg diborane
Electrochemistry Mg-borates in KCL
Other chemical routes ??

9
Materials Requirements

Magnetic Fields 2-5 T (except cables)
AC use requires T gt 20 K (cryogenic cost)
Materials parameters
Low cost 10 /kA.m
Practical volumes Je (Jc 105 A/cm2 )
Low AC losses W/kA.m at 50Hz.
Flexible, low Je / strain sensitivity

10
Targets

Copper 6 22 /kA.m (400 to 100 A/cm2)
Bi2223 100 25 /kA.m (2002 2005)

Device kA/cm2 T /kA.m
Motor 105 4 10
Generator 105 4 10
Transformer 8.104 0.5 - 2 lt10
FCL 8.104 0.2 10
Cable 7.104 lt0.5 10-100
Dick Blaugher, NREL
11
Market Segmentation
12
Competitive Costs
Wire /kA.m Cost Driver
NbTi (4.2 K, 2 T) 0.90 Materials (Nb)
Nb3Sn (4.2 K, 10 T) 10 Materials (Nb)
Bi-2223 (25 K, 1 T) 25 Materials (Ag)
Y-123 (25 K, 1 T) 4 Capital Plant
MgB2 (25 K, 1 T) 0.8 3.6 ? Capital Plant
Paul Grant EPRI
13
Comparative Performance
"Sokolowski Plot" of HTSC Wire Performance and
Cost
10000
10
1 /kAm
100
NbTi
4.2K, 2T
1,000
1000
Nb
Sn
3
4.2K, 12-15 T
Operating Current, Ic (A)
100
Y-123 IBAD 77K, 0T
Bi-2223 77K,0T ASC 50
Bi-2223
77K, 0T
10
NKT Target
1
1000
100
10
1
0.1
Cost (/m)
Paul Grant EPRI
14
Transformers a big prizeCost of Ownership in
/kW
Cu (300 K) _at_ 300 A/cm2 HTS (68 K) MgB2 (25 K)
Losses 60
Cryo -
Wire 5
Total 65
2000 ABB SPI Phase I Analysis
Paul Grant EPRI
15
First Major Applications

Current Leads? No.
FCLs ? New capabilities!
Transmission Cables ?
Distribution Cables ?
Dielectric thermal AC lossses
Transformers ? 98 efficient.
Generators ?
Power stations,Wind turbines?
Non-Utility Power Applications
Motors
68 of industrial power
Half of that over 750kW
Power electronics Cryogenics

16
Materials Changeovers
Materials Changeovers
17
Technology S Curves
18
Power Technologies
75y
16y
MgB2
Performance
HTCs
Copper-Iron
2002
Effort
19
Conclusions