Post on 18-Jun-2018
Anodes for Direct Hydrocarbon Solid Anodes for Direct Hydrocarbon Solid Oxide Fuel Cells (SOFCOxide Fuel Cells (SOFC’’s) s)
Challenges in Challenges in –– materials selection and materials selection and depositiondeposition
VenkatesanVenkatesan V. KrishnanV. KrishnanDepartment of Chemical EngineeringDepartment of Chemical Engineering
IIT DelhiIIT Delhi
Barriers to the hydrogen economyBarriers to the hydrogen economy• How to make hydrogen (SR, electrolysis, Solar, Borohydride)?
• Loss of efficiency in making hydrogen
• Storage and Transportation?
• SOFC’s can work with any ‘fuel’
• Let us work in parallel with the Hydrogen advocates by using hydrocarbons directly with SOFC’s
• Do not forget – well to wheels efficiency!
DIRECT OXIDATION OF DIRECT OXIDATION OF HYDROCARBONS AND OXYGENATESHYDROCARBONS AND OXYGENATES
Reactions:Cathode: (x + y/4 - z/2) O2 + (4x + y- 2z) e (2x + y/2 - z) O2-
Anode: CxHyOz + (2x + y/2 - z) O2- (y/2) H2O + x CO2 + (4x + y - 2z) e
Overall: CxHyOz + (x + y/4 - z/2) O2 (y/2) H2O + x CO2
Natural Gas, Propane/ Butane (LPG), Naphtha, Diesel, Alcohols,Natural Gas, Propane/ Butane (LPG), Naphtha, Diesel, Alcohols,Syngas (from coal and biomass) Syngas (from coal and biomass)
WHAT HAPPENS IN THE ANODE IN SUCH CASES ? WHAT HAPPENS IN THE ANODE IN SUCH CASES ? -- Direct oxidation; Direct oxidation; CHCH44 + 4O+ 4O22-- COCO22 + 2H+ 2H22O + 4eO + 4e-- Internal reforming; Internal reforming; CHCH44 + H+ H22O O CO + 3HCO + 3H22
-- Syngas oxidation; Syngas oxidation; CO + HCO + H22 + O+ O22-- COCO22 + H+ H22OO-- Coke deposition (thermal, catalytic); Coke deposition (thermal, catalytic); CHCH44 CHCHxx + H+ H22
WHY DO WE NEED NEW ANODESWHY DO WE NEED NEW ANODES
•• Incompatibility of NiIncompatibility of Ni--YSZ anodes with any fuel other YSZ anodes with any fuel other than Hthan H22 –– reforming essential; reforming essential; coking with dry coking with dry hydrocarbonshydrocarbons Reference: Toebes et al.Reference: Toebes et al.
•• Poisoning of NiPoisoning of Ni--YSZ by YSZ by sulfur compoundssulfur compounds•• Poor Redox tolerancePoor Redox tolerance of Niof Ni--based anodesbased anodes•• YET, must satisfy the basic needs of SOFC anodes YET, must satisfy the basic needs of SOFC anodes ––
–– Electronic conductivityElectronic conductivity–– Ionic conductivityIonic conductivity–– Good catalytic activityGood catalytic activity–– Compatibility of Compatibility of CTECTE’’ss with that of electrolytewith that of electrolyte
EFFECT OF COKING ON NiEFFECT OF COKING ON Ni--YSZ ANODESYSZ ANODES20% CO/7% H2550°C. Ni particles
Coking due to decomposition and/or Bouduard Reaction
In H2, 800oC, 3 hrs In CH4, 800oC, 3 hrs
Toebes et al. (2002)Toebes et al. (2002)
ALTERNATIVE ANODES ?ALTERNATIVE ANODES ?Perovskites, Irvine et al.Perovskites, Irvine et al.BoukampBoukamp, et al. , et al.
AABBOO33
Lanthanides/ Alkali earth Metal ionsOxygen ionsTransition metal ions
Cu/CeOCu/CeO22/YSZ/YSZ Gorte et al. (2000)Gorte et al. (2000)
CeCe0.90.9GdGd0.10.1OO1.95 1.95 combined withcombined with
(La(La0.80.8SrSr0.20.2) (Cr) (Cr0.80.8MnMn0.20.2)O)O33--δδ
Barnett et al. (2002)Barnett et al. (2002)
Irvine et al. (2001)Irvine et al. (2001)
TitaniaTitania--Niobia, NbNiobia, Nb22TiOTiO77--xx
Irvine et. al. (2003)Irvine et. al. (2003) ––(La(La0.80.8SrSr0.20.2) (Cr) (Cr0.50.5MnMn0.50.5)O)O33--δδ
Why perovskites???Why perovskites???
•• Ionic and electronic conductivity can be tailoredIonic and electronic conductivity can be tailored
•• Good Hydrocarbon oxidation catalytic activity has been Good Hydrocarbon oxidation catalytic activity has been reported.reported.
•• No cokingNo coking
•• Good thermal and redox stabilityGood thermal and redox stability
•• And yet, concern remains And yet, concern remains –– do we have adequate do we have adequate electronic conductivity under reducing conditions?electronic conductivity under reducing conditions?
Review of work on alternate anodes Review of work on alternate anodes -- Gorte et al.Gorte et al.• Anodes based on Copper – conductor; Ceria – electrocatalyst
– Cu and CeO2 deposited on pre-formed porous anode substrates– Intermediate temperature SOFC’s
• Considerable data on butane, methane, diesel, propane –– Anode stable over long periods of time– Direct electrochemical Oxidation observed in button cells– Workable with fuel with existing sulfur levels
• Technology transfer to Franklin Fuel Cells, PA, US– Demonstration level, with diesel, gasoline and ethanol
• Performance tends to be lowered due to Copper sintering; enhancement necessary by carbon deposition
• Little/ no data on redox tolerance (deposition technique may be advantageous, use of Vol % < 20%)
Gorte et al., contGorte et al., cont’’dd
0.0
0.3
0.6
0.9
1.2
1.5
0.0 0.2 0.4 0.6 0.80.00
0.04
0.08
0.12
0.16
0.20
V P
I, A/cm2
A B
C
C
0.0
0.3
0.6
0.9
1.2
1.5
0.0 0.2 0.4 0.6 0.80.00
0.04
0.08
0.12
0.16
0.20
V P
I, A/cm2
A B
C
C
1E-03
1E-01
1E+01
1E+03
1E+05
0 5 10 15 20 25 30
Volume Percent Cu, %
Effe
ctiv
e Co
nduc
tivity
, S/c
m
Overall ‘connectivity’ of Cu is good, leading to about 4300 S/cm (from 4-point probe)
Compare with Ni-YSZ made by solid state methods
Performance, Conductivity with Cu contentPerformance, Conductivity with Cu content• Carbon enhancement
occurs even at 25% Vol Cu; constant, independent of Cu
• But sufficient conductivity is attained with less than 10% volume
Volume fraction of Cu
σ, C
o nd u
c tiv
ity, S
/cm
Max
. P D
, W/c
m2(w) carbon
Conductivity(w/o) carbon
Performance
Overall conductivity not the problem; the issue is proper ‘connectivity’ at the 3-phase boundary
0
1000
2000
3000
4000
5000
0.00 0.05 0.10 0.15 0.20 0.25 0.300.00
0.05
0.10
0.15
0.20
0.25
Irvine et al. (2003)Irvine et al. (2003) (La(La0.750.75 SrSr0.250.25 CrCr0.50.5 MnMn0.50.5 OO33--δδ), ), LSCMLSCM
Conductivity of perovskite at 850oC- in air, 28 S/cm- in reducing atmosphere, 1.12 S/cm
Max. P. D. (W/cm2) = 0.47, 900oCMax. P. D. in Methane = 0.3 W/cm2
(at 950oC)
Irvine et al., NiobiaIrvine et al., Niobia--Titania rutile system (2001)Titania rutile system (2001)
Reduction
•• Max. conductivity under reduction, 300 S/cmMax. conductivity under reduction, 300 S/cm•• Good catalytic activity towards methane Good catalytic activity towards methane
OxidationOxidation
Barnett et al. (2002) Barnett et al. (2002) –– LSCMLSCM--GDC composite GDC composite
• Usage of LSCM – high electronic conductivity in reducing conditions, as well
• Compatible with GDC electrolytes
Small qty of Ni +Small qty of Ni +CeCe0.90.9GdGd0.10.1OO1.951.95 –– ionic conductionionic conduction
(La(La0.80.8SrSr0.20.2) (Cr) (Cr0.80.8MnMn0.20.2)O)O33--δδ −− electronic conduction electronic conduction
Compared to NiCompared to Ni--GDC, performance in CGDC, performance in C33HH88 is significantly higheris significantly higher
Focus of research at Chemical Eng. Dept., IITFocus of research at Chemical Eng. Dept., IIT--DD•• Nature of work essentially fundamental Nature of work essentially fundamental -- ‘‘button cellsbutton cells’’•• Aim is to contribute to existing knowledge Aim is to contribute to existing knowledge ‘‘poolpool’’, via publications , via publications
and patents by addressing problems involving Electrochemistry, and patents by addressing problems involving Electrochemistry, Materials and CatalysisMaterials and Catalysis
•• We look forward to collaborate with We look forward to collaborate with ‘‘developmental laboratoriesdevelopmental laboratories’’, , e.g., test our ideas on a larger scale e.g., test our ideas on a larger scale –– CGCRI, BHEL R&DCGCRI, BHEL R&D
What we are involved in What we are involved in --•• SOFC component fabrication SOFC component fabrication –– tape casting, sintering, painting, tape casting, sintering, painting,
impregnationimpregnation•• Characterization of components Characterization of components –– bibi--layers, catalysts layers, catalysts –– SEM, SA/ SEM, SA/
PSD, Porosity, XRD, Thermal AnalysisPSD, Porosity, XRD, Thermal Analysis•• Testing of Electrical ConductivityTesting of Electrical Conductivity•• Fuel Cell TestingFuel Cell Testing
FUEL CELL REACTOR AND OPERATIONFUEL CELL REACTOR AND OPERATION
Fuel
Air
Cathode Lead (Ag/ Pt)
Anode Lead, Au
Ag/ Pt mesh
LSM-YSZ Cathode
Anode
Ceramabond, adhesive
1/2” OD Alumina tube
Tape Casting (nonTape Casting (non--AqAq))
1.2m LPEGPlasticizer2.0gPV BB inder0.5m LO leic A cidD ispersant10m LEtO H20m LM E KSolvent15gY SZPow der
Q uantityC om ponentC om ponent function
1.2m LPEGPlasticizer2.0gPV BB inder0.5m LO leic A cidD ispersant10m LEtO H20m LM E KSolvent15gY SZPow der
Q uantityC om ponentC om ponent function
Characterization of tapeCharacterization of tapeSEM of Graphite – as received
SEM of sintered bilayer
Electrolyte
TG/DTA of Electrolyte Tape
13
13.5
14
14.5
15
15.5
16
16.5
17
17.5
0 200 400 600 800 1000 1200 1400 1600
Temp (C)
wei
ght
(mg
)
-40
-30
-20
-10
0
10
20
30
uV
tgaDTA
Less than 500oC
Anode Preparation by Perovskite DepositionAnode Preparation by Perovskite Deposition
This method is totally different from the mixing and solidThis method is totally different from the mixing and solid--statestatesynthesis techniques listed in most literature.synthesis techniques listed in most literature.Moving away from the 3Moving away from the 3--phase boundary limitation to a 2phase boundary limitation to a 2--phase boundary situationphase boundary situation
Impregnation & calcination
Final Anode Structure
Porous anode matrix
Three Phase Boundary
back
e-
e-
e- e-
e- e-
Two Phase BoundaryTwo Phase Boundary-- a new approacha new approachfuel
electrolyte
anode
back
SEM and XRD both confirm that the required phase is formed inside the pores. But conductivity is very low i.e., 10But conductivity is very low i.e., 10--2 2 S/cm.S/cm.
Impregnated La Impregnated La CrOxCrOx on preformed anodeson preformed anodes
Perovskites depositedLaCrO3La0.75Sr0.25CrO3
La0.9Sr0.1CrO3
StarchStarch
Morphology of biMorphology of bi--layerslayers
• Investigation of pore sizes –choice of pore-formers, like Graphite, Starch, PMMA to name a few
• Porosity• Pore size distributionWhich are dependent on –• Particle sizes• Particle size distribution• Particle ‘shapes’
Tailoring the porosity of anodeTailoring the porosity of anode
Removal of pore formers by 950oC, completely
05
101520253035404550
0 200 400 600 800 1000 1200 1400 1600
Temp C
% re
d in
wei
ght
-30
-25
-20
-15
-10
-5
0
5
10
uV
TGADTA
TGA/DTA of Anode, in air;TGA/DTA of Anode, in air;Pore former is 50% Graphite (Alfa Pore former is 50% Graphite (Alfa AesarAesar))
TGATGA--DTA of anode pellet withDTA of anode pellet with30% graphite in N30% graphite in N22 atmatm
-2
0
2
4
6
8
100 200 400 600 800 1000 1200 1400
Temp C%
wei
ght L
oss
-30
-25
-20
-15
-10
-5
0
5
uV
TGADTA
Removal of pore formers only begins at 1100oC
Sintering temperature is usually 1450Sintering temperature is usually 1450ooC up to 1550C up to 1550ooCCPore structure may have a strong dependence on temperaturePore structure may have a strong dependence on temperatureof removal of pore formerof removal of pore former
Work in ProgressWork in Progress
• Preparation and testing of – chromites, titanates, niobates and vanadates
• Impregnation of perovskites onto pre-formed anode substructure
• Conductivity data on oxides as electrocatalysts under reducing conditions – redox stability of oxides, as well
• Systematic investigation of pore and particle morphology
• Testing of anode supported cells on various fuels