A Flow Battery for Grid -Scale Energy Storage€¦ · A Flow Battery for Grid -Scale Energy Storage...
Transcript of A Flow Battery for Grid -Scale Energy Storage€¦ · A Flow Battery for Grid -Scale Energy Storage...
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A Flow Battery for A Flow Battery for
GridGrid--Scale Energy StorageScale Energy Storage
Vincent Battaglia
Principal Investigator
LBNL
February 22, 2012
NCCAVS ConferenceSan Jose, CA
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Renewable energy standards (e.g., 30% renewables by 2020 in California) will require s
form of energy back-up
New CA state bills require CPUC to examine targets for procurement of energy storage systems
GWh of storage needed in a decade
Potentially a very large market ($100B); in contrast, vehicle market expected to be $16
year by 2020.
Renewable Firming2-8 h, $28.6B
Load Following2-4 h, $28 B
Time shift Renewables1-8 h, $36 B
Frequency Regulation<1 h, $4.9 B
Source: Extracted from E
Need a source of back-up electricity in the range of 1 to 8 h;
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• Stabilize grid power at 60Hz givenintermittent generation assets (insolar, wind)
• Requirements
� High power (MW)
� Fast ramp rate (seconds)
� High efficiency (70-90%)
� Short discharge times (< 1 hour)
California ISO – Integration of Renewable Resources Nov 2007
24h
Wind
Solar
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Time shifting of intermittent assets to high-value periods
Similar requirements to Grid Reliability, but longer discharge times
~ 2 to 3 day
MW
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• Capture low-cost electricity for peak us
• Replace spinning reserves
• Provide backup for “Never-Off” system
• Industrial, commercial, institutional customers
• Siting near point-of-use
� Perceived safety is critical – may hinder adoption
* Vermont State Electric Plan (2005)
$/M
W
Batteries can be designed to meet all of thesrequirements, and in some cases,
simultaneously.Simply design to the largest energy and power requirements,
then verify overall cost reduction
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Traditional Battery
High energy density
Ex. LiCoO2; concentration of Li = 46 mol Li/l of oxide =
1230 Ah/l
Voltage = 3.6
Lower power density
Resistance ~ 30 ohm cm2 due to solid state diffusion
Cost a function of E/P
Total Cost ($/kWh) ~ 600x(P/E)1/2
~ 600x(1/td)1/21/21/21/2
The cost of constructing the battery with the
proper energy and power are coupled.
Cost related to high cost of active materials.
• Flow Battery
� Low energy density
� Ex. 1 M Br2 solutions = 54 Ah/l (factor of 23 tim
� V = 1 V
� High power density
� Resistance ~ 0.3 ohm cm2 (a factor of 100 time
� Cost
� The power and energy are literally separate en
Power unit Tanks
Total Cost ($/kWh) = ($/kW)/td + $/kWh
= $/m2*ASR/[ηηηη1/2(1-ηηηη1/2)U2)]/td
These batteries are preferred if you can co
inexpensive materials with a high-rate pow
•Low resistance
•High voltage but within electrolyte stabili
Both can be designed to meet the power and energy
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Four important metrics: Performance (energy efficiency rather than energy density), cost, life, and safety
Historically, choice of battery is a compromise
For grid storage, main challenge is cost. Target: $100/kWh (gas turbine)
Targe
High-volume cost projections for Li-ion batteries
Source: TIAX, DOEMerit Review, 20
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Requirements:
Need good reversibility
Need chemicals that are inexpensive
Need inexpensive cell components
Need a high power device
Higher the power, lower the number of cells
No structural changes (e.g., plating)
• Separation of energy and power
• Energy dictated by size of tanks
• Power depends on size of cell
• Cell is typically expensive
Increasing power
1200
Cell
Tanks
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Br2/HBr
H2
HBr
Ion-exchange/micropmembrane
Ion-exchange/micropmembrane
Pt-based catalystmembrane
Pt-based catalystmembrane
Carbon felt catalyst support layer
Carbon felt catalyst support layer
Ch
arg
e
Dis
charg
e
Gas diffusion suppolayer
Gas diffusion suppolayer
H2 ↔ 2H+ + 2eBr2 + 2H+ + 2e ↔ 2HBr
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Total cell resistance = Ohmic+charge transfer+mastransfer
Membranes and contact
Kinetically fast reactions
Better cell design
Rotating disc studies
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0.2 0.4 0.6 0.8 1.0 1.2
0.9M Br2/1M HBr with thick carbon-felt
Current Density (A/cm2)
0.0
0.2
0.4
0.6
0.8
Po
wer
Den
sit
y (
W/c
m2)
• Carbon-felt electrode:
Max. performance: 0.6
Typical flow batteries
Temperature: RT; flowrate: 200 ml/min
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0.2 0.4 0.6 0.8 1.0 1.2
0.9M Br2/1M HBr with thick carbon-felt
0.9M Br2/1M HBr with multilayer carbon-felt
Current Density (A/cm2)
0.0
0.2
0.4
0.6
0.8
Po
wer
Den
sit
y (
W/c
m2)
• Carbon-felt electrode:
Max. performance: 0.6
• Multi-layered C-felt el
Max. performance: 0.7
Typical flow batteries
Temperature: RT; flowrate: 200 ml/min
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0.2 0.4 0.6 0.8 1.0 1.2 1.4
0.9M Br2/1.0M HBr
4.0M Br2/1.0M HBr
2.0M Br2/0.5M HBr
Current Density (A/cm2)
0.0
0.2
0.4
0.6
0.8
1.0
Po
wer
Den
sit
y (
W/c
m2)
•Multi-layered C-felt ele
Max. performance: 0.7
•Optimized electrolyte
Max. performance: 0.9
Temperature: RT; flowrate: 200 ml/min
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Discharge performanceDischarge performance
Max PD
(W/cm2)%
Ma
(A/
Baseline 0.68 0.0 1
2M Br2/0.5M HBr
(No pretreat)0.89 31.7 1
0.9M Br2/1M HBr
(H2SO4 pretreated)0.92 36.2 1
1M Br2/0.5M HBr
(H2SO4 pretreated)0.97 43.5 1
Performance from pretreated PM with H2SO4 was very reliable
Max power : 0.92 (0.9M Br2/1M HBr) and 0.97 (1M Br2/0.5M HBr)
Max current density: 1.54 A/cm2
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6
Baseline (no pretreat) 2M Br2/0.5M HBr (no pretreat) 0.9M Br2/0.5M HBr (H
2SO
4 5hrs)
1M Br2/0.5M HBr (H2SO
4 5hrs)
Pretreatment: H2SO
4 5hrs
Current Density (A/cm2)
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
Po
wer
Den
sit
y (
W/c
m2)
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Highly reversible;no side reactions
@ Room Temperature
0.0 0.2 0.4 0.6 0.840
50
60
70
80
90
100
Discharge
Cell e
ffic
ien
cy (
%)
Power density (W/cm2)
High power at highefficiencies
Discharge
Power density (W/cm2)C
ell e
ffic
ien
cy (
%)
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6
Discharge
Charge
Current density (A/cm2)
0.0
0.4
0.8
1.2
1.6
2.0
2.4
Po
wer
den
sit
y (
W/c
m2)
Po
wer
den
sit
y (
W/c
m2)
Charge
DischargePower
Voltage
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800
600
400
200
0
Sta
ck +
BO
P +
Assem
bly
ca
pital co
st
($/k
Wh)
86420
Discharge time (hours)
Gen1 Gen2 Gen3 Gen4 With further optimization
Nafion limit (0.1 ohm-cm2)
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Cost Breakdown for “Nafion Limited”
Br liq. pump: 26%
Br tank: 16%
H2 tank: 24%
Active matls.: 22%
Sensors, cables, other: 13%
BOP cost = 158 $/kWh
Membrane: 48%
H2 electrode catal.: 5%
Electrodes (no c
GDL/F
Bipo
Gasket & se
Endplates & tie rods: 4%
Stack cost = 97 $/kWh
Energy Power
Either pay for the H2 tanks and BP plates or pay for the pumps.
Focus on reducing membraand bipolar plate costs.
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Br2 is a problem as it’s toxic with a low vapor press(boils at 58.8oC)
But perhaps we can find a complexing agent that
keeps it in solution while maintaining its performan
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0.9M Br2/1M HBr with thick carbon-felt
0.9M Br2/1M HBr with multilayer carbon-felt
4M Br2/1M HBr with multilayer carbon-felt
0.0
0.2
0.4
0.6
0.8
Po
wer
Den
sit
y (
W/c
m2)
Increasing power
Flow batteries have the potential to be cost effective
today for large discharge times
Flow batteries have the Flow batteries have the
potential to be cost effective potential to be cost effective
today for large discharge timestoday for large discharge times
Promising power performance. Better than
competing systems
Promising power Promising power
performance. Better than performance. Better than
competing systemscompeting systems
Can we make the chemistrsafe?
Can we make the chemistrCan we make the chemistr
safe?safe?
Hydrogen-Bromine chemistry hvery fast charge transfer kinetiExpensive catalysts not neede
for the bromine electrode.
HydrogenHydrogen--Bromine chemistry hBromine chemistry h
very fast charge transfer kinetivery fast charge transfer kineti
Expensive catalysts not needeExpensive catalysts not neede
for the bromine electrode.for the bromine electrode.
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Funding from ARPA-E
Kyu Taek Cho (Cell studies)Paul Ridgeway (Catalysis studies)Sophia Haussener (Transport modeling)
Paul Albertus (Cost Modeling)Roel Sanchez-Carrera and Boris Kozinsky (Catalyst theory)
Biswajit Choudhury (New membranes)
Mark Debe (Catalyst structures)
Proton OnSite: