Water Transport Exploratory Studies - US Department of...
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Water Transport Exploratory Studies Office of Hydrogen, Fuel Cells, and Infrastructure Technologies 2007 kickoff meeting February 13-14, 2007 DOE Forrestal Building Rod Borup Mukundan Rangachary, Bryan Pivovar, Yu Seung Kim, John Davey, David Wood, Tom Springer, Muhammad Arif , Ken Chen, Simon Cleghorn, Will Johnson, Karren More, Peter Wilde, Tom Zawodzinski Los Alamos National Lab This presentation does not contain any proprietary or confidential information
Transcript of Water Transport Exploratory Studies - US Department of...
Water Transport Exploratory Studies Office of Hydrogen, Fuel Cells, and Infrastructure Technologies 2007
kickoff meeting
February 13-14, 2007DOE Forrestal Building
Rod BorupMukundan Rangachary, Bryan Pivovar, Yu Seung Kim, John
Davey, David Wood, Tom Springer, Muhammad Arif , Ken Chen, Simon Cleghorn, Will Johnson, Karren More, Peter
Wilde, Tom Zawodzinski
Los Alamos National LabThis presentation does not contain any proprietary or confidential information
Objectives• Develop understanding of water transport in PEM
Fuel Cells (non-design-specific) • Evaluate structural and surface properties of materials
affecting water transport and performance • Develop (enable) new components and operating
methods • Accurately model water transport within the fuel cell• Develop a better understanding of the effects of
freeze/thaw cycles and operation • Present and publish results
Technical Targets/Barriers
N. Vanderborgh, 1994 “...... it’s all about water management ...”
≤1.550kPa (absolute)
Inlet water vapor partial pressure
20102004UnitsCharacteristic
Technical Targets:
Status
Membranes
Approach• Develop understanding of water transport
– Experimental measurement and testing – Characterization – Modeling
• Evaluate structural and surface properties of materials affecting water transport and performance – Measure/model structural and surface properties of material
components – Determine how material properties of GDL, MPL, catalyst layers
& interfaces affect water transport (and performance) – Determine properties change during operation (degradation effects)
• Develop (enable) new components and operating methods – Prevent flooding (high power operation) – Prevent dehumidification (low RH operation - transportation)
• Develop a better understanding of the effects of freeze/thaw cycles and operation – Help guide mitigation strategies.
Prior Work
• Prior relevant work includes (LANL):– Modeling of mass transport losses – Freeze/thaw – GDL characterization (durability)
• More team relevant prior work – Modeling – Electro-osmotic drag measurements
– MEA / GDL manufacturing (etc.) – Characterization – Neutron imaging
0.5
0.6
0.7
0.8
0.9
1.0
MEA Overpotential Losses (Modeling to delineate degradation losses)
• Increase in cathode GDL mass-transport Overpotential
• Hydrophobicity loss
Constant Current Operation @ 0.90 A/cm2
η
η
η
Vi
( )
⇒T⇒ / 15
⇒⇒ /( /cm2
Catalyst-Layer Mass-Transport Improvement from More
Hydrated Electrode Ionomer
Time, tx,GDL
Time, tx,elec
Time, ORR
Time, R-free
Solid Symbols = 0 hr Beginning of LifeGray Symbols = 536 hr Durability Testing
White Symbols = 1014 hr Durability Testing
cell = 80°C Gas Pressure = 15
psig (A/C) RH = 75% / 75% (A/C) Flow Rates = 1.2 2.0
A/C) × 1.5 A equiv.
0.45
• Decrease in cathode electrode mass transport overpotential
• Decrease in HFR
0.40
0.35
0.30
• Increase in ORR overpotential
• S.A. decrease η (V
)
0.25
0.20
0.15
0.10
0.05
0.00
-0.05 0.00 0.25 0.50 0.75 1.00 1.25 1.50
Current Density (A/cm2)
V i R
-free
(V)
Changes in mass-transport (Æ water management)
0.4
GDL Fiber Chemistry and Contact Angle96
78
80
82
84
86
88
90
92
94
Unaged N2, 60°C,
)
f
77
81
85
89
93
97
(θ °)
Hy
Unaged Unaged N2, 80°C, Air, 60°C, Air, 80°C,
Con
tact
Ang
le (d
eg Hydrophobic
Hydrophilic
Increasing Aggressiveness oAging Environment
Con
tact
Ang
le (d
eg)
5 wt% PTFE 20 wt% PTFE
Plain TGP-H Fiber = 80.3
Increasing Graphitization Temperature
drophobic Hydrophilic
SGL GDL 24 Spectracorp 2050-C Toray TGP-H TGP-H 120 TGP-H 090 TGP-H 090 460 hr; 460 hr; 680 hr; 680 hr; GDL Graphite Fiber Type (Plain) #1 (17.2 #2 (17.0 TGP-H 060 TGP-H 090 TGP-H 060 TGP-H 090
wt% FEP) wt% FEP) (17.2 wt% (16.7 wt% (16.9 wt% (17.0 wt% FEP) FEP) FEP) FEP)
• Fiber graphitization can increase single-fiber contact angle ~ 10°
• Both graphitization T and PTFE loading can change the liquid-water wetting regime of the GDL substrate.
Before/After SEM Comparison of PTFE Microstructure of GDL
Fresh After Testing
• Loss of definition delineating the individual PTFE particles – (typically shaped like and ellipsoid and 200-500 nm diameter).
• Features could be associated with changes in liquid water transport characteristics or carbon fiber surface changes.
• Features are also affected by sintering time and temperature.SIGRACET GDL 24BC
Freeze/Thaw cycling
GDL: carbon paper (SGL), Active area: 5 cm2
Confocal laser imaging Dr. Mike Hickner Sandia National Lab
• No systematic degradation observed up to 45cycles • Mechanical Failure @ 45 cycles • Fiber breakage at land/channel edge is a potential failure mechanism
• More tests required to investigate failure mechanisms
Water Transport Exploratory Studies Project initiated in FY2007 for 4 years
Segmented cell studies/
transient operation
Water balance thawing
Conductivity of
down to -40 oC
water content steady-state and transient conditions
2007 2008 2009 2010
Quasi-3D model for simulating electrode layers
in situ water/ice imaging neutron
Start GDL surface properties
aging effects
100 freeze/thaw
crystallinity
MEA properties < 0 oC / effect of freeze/thaw cyclingshutdown
cycles on ionomer Component water removal during
Qtr. 4 based on Reasonable 1D Prediction)
Qtr. 6
Qtr. 10
Qtr. 10
Go/No-Go
o
oC) will be explored in further studies.
Demonstrate 1-D model validity in case studies. (Go/No Go Decision to Proceed to 3D
Demonstrate start up fuel cells from -20 C. Only materials and conditions that meet this decision criterion (start up from –20
z-direction imaging capability by neutrons. If not capable of performing tomography at this point, we will conclude the neutron imaging work.
Electro-osmotic drag coefficient measurements. Activity gradient cells vs. electrophoretic NMR measurements.
Organizations / Partners
• Los Alamos National Lab – (Lead: experimental measurements, modeling)
• Sandia National Laboratory (modeling) • Case Western Reserve University
(characterization, modeling) • W. L. Gore and Associates, Inc. (MEAs) • SGL Carbon Group (GDLs, MPLs) • Oak Ridge National Lab (characterization)• National Institute of Standards and Technology
(neutron imaging)
Budget
DOE Cost Share Recipient Cost TOTAL Share
$6,550,000 $290,811 $6,840,811
96% 4% 100%
FY07 LANL $1000k
Industrial Partners (Gore/SGL/CWRU) $300k Other National Labs (SNL/ORNL) (?) $350k FY07 Total 1650
Input / Needs• Automotive OEM (FC Tech Team) definition of
inlet RH as a function of power/time during operating drive cycles
Wat
ts
Volts
20 min
AM
PS
W
atts
Volts
W
atts
Am
ps
6 min
VO
LTS
