controlled hydrogen fleet and infrastructure analysis · – objectively assess progress toward...
TRANSCRIPT
NREL is a national laboratory of the U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy, operated by the Alliance for Sustainable Energy, LLC.
Controlled Hydrogen Fleet and Infrastructure Analysis
2012 DOE Annual Merit Review and Peer Evaluation Meeting
Keith Wipke, Sam Sprik, Jennifer Kurtz, Todd Ramsden, Chris Ainscough, Genevieve Saur
May 17, 2012: Washington, DC
NREL/PR-5600-54475
This presentation does not contain any proprietary, confidential, or otherwise restricted information
Project ID# TV001
V2, 4/5/12
2
Fuel Cell Electric Vehicle Learning Demo Project Objectives, Relevance, and Targets • Objectives
– Validate H2 FC Vehicles and Infrastructure in Real-World Setting – Identify Current Status and Evolution of the Technology
• Relevance – Objectively Assess Progress Toward Targets and Market Needs – Provide Feedback to H2 Research and Development – Publish Results for Key Stakeholder Use and Investment Decisions
APC/Shell Pipeline station, Torrance, CA. Photo: NREL
Performance Measure Interim (2009)*
Ultimate (2020)
Fuel Cell Stack Durability 2000 hours 5000 hours
Vehicle Range 250+ miles 300+ miles
Hydrogen Cost at Station $3/gge $2-4/gge**
Key Targets
*Project extended 2 years through 2011; **Previously $2-3/gge for 2015
Outside review panel
Details of each of these 3 results in technical backup slides (previous AMR)
3
Project Overview
• Project start: FY03 • Project end: FY12 • 98% of Task III complete (see timeline slide)
A. Vehicles – lack of controlled & on-road H2 vehicle and FC system data
B. Storage – technology does not yet provide necessary 300+ mile range
C. Hydrogen Refueling Infrastructure – cost and availability
D. Maintenance and Training Facilities – lack of facilities and trained personnel
E. Codes and Standards – lack of adoption/validation
H. Hydrogen Production from Renewables – need for cost, durability, efficiency data for vehicular application
I. H2 and Electricity Co-Production – cost and durability
• Funding prior to FY11 : $5517K • FY11 funding: $650K • Planned FY12 funding: $400K ($6,567K total over 10 fiscal years)*
Timeline
Budget
Tech. Val. Barriers
• See partner slide
Partners
*Related OEM/energy Learning Demonstration projects received $170M DOE funding and provided $189M cost-share for a total of $359M
4
Approach and Accomplishments: Project Timeline and Major Milestones
Task I – Project Preparation [100% Complete]
Task II – Project Launch [100% Complete]
Task III – Data Analysis and Feedback to R&D activities (partial list) [98% Complete] 8 Publication of first “composite data products” 9 Evaluate FC stack time to 10% voltage degradation relative to 1000-hour target 10 Decision for purchase of additional vehicles based on performance, durability, cost 11 Preliminary evaluation of dominant real-world factors influencing FC degradation 12 Introduction of 2nd generation FC systems into vehicles begins 13 FCVs demonstrate 250-mile range without impacting passenger cargo compartment 14 Validate FCVs with 2,000 hour durability and $3.00/gge (based on volume production) 15 Data analysis continues with data from 2 of the 4 OEM/Energy teams plus CHIP stations 16 Conclusion of data submission to NREL on pre-commercial FCEVs (Sept. 2011) 17 DOE Milestone: Validate 40 adv. technology FCEVs with up to 600 hours operation 18 Final data analysis and report on Learning Demonstration 19 Preparation for next FCEV validation project
4
Task I 1 2 3
Task II 5 6
Task III 7 14 10
NREL Quarterly Analysis of Data
9
5/06
11
5/05
8
FY03 FY04 FY05 FY06 FY07 FY08 FY09
5/07
12 13
6/08 5/04
FY10
5/09
15
FY11
6/10
16 18
FY12
5/11
17
2 teams concluded their projects
5/12
19
Gen
1 G
en 1
+
Gen
2 2
OEM
s
5
Project Approach
• Provide facility and staff for securing and analyzing industry sensitive data o NREL Hydrogen Secure Data Center (HSDC)
• Perform analysis using detailed data in HSDC to: o Evaluate current status and progress toward targets o Feed back current technical challenges and
opportunities into DOE H2 R&D program o Provide originating companies with analytical
results on their own data (detailed data products) o Collaborate with industry partners on new analyses
• Publish/present progress of project to public and stakeholders (composite data products)
6
CDPs
DDPs
Public
Composite Data Products (CDPs) • Aggregated data across multiple systems,
sites, and teams • Publish analysis results every six months
without revealing proprietary data2
Detailed Data Products (DDPs) • Individual data analyses
• Identify individual contribution to CDPs • Shared every six months only with the
partner who supplied the data1
1) Data exchange may happen more frequently based on data, analysis, & collaboration 2) Results published via NREL Tech Val website, conferences, and reports (http://www.nrel.gov/hydrogen/proj_learning_demo.html)
Project Approach (cont.) Supporting Both DOE/Public as Well as Technology Developers
Results
Bundled data (operation & maintenance/safety) delivered
to NREL quarterly
Internal analysis completed quarterly
7
Industry Partners: Collaborative Relationship, Working Through Details of Analysis, was Critical to Success
Gen 1 & 2 Gen 1 Gen 2
Ford/BP and Chevron/Hyundai-Kia Participated Through 2009
Gen 1
Gen 2 Gen 2
Gen 1
Collaboration with Daimler, GM, and Air Products;
(CHIP)*
*CHIP = California Hydrogen Infrastructure Project
Data in the Last Year (through Sept.) came from These 3 Companies
8
4
83
45
51
-
20
40
60
80
100
120
140
160
180
200
Cum
ulat
ive
Vehi
cles
Dep
loye
d/R
etire
d1
Vehicle Deployment by On-Board Hydrogen Storage Type
700 bar on-road350 bar on-roadLiquid H2 on-road700 bar retired350 bar retiredLiquid H2 retired
(1) Retired vehicles have left DOE fleet and are no longer providing data to NREL(2) Two project teams concluded in Fall/Winter 2009Created Dec-13-11 3:12 PM
183
NREL cdp_fcev_25
(2)
Vehicle Status: All Project Vehicles in the Last Two Years Were Using 700 bar Storage
51 vehicles on road 132 retired
Large # vehicles required for statistical
significance
9
7
12
6
0
5
10
15
20
25
Num
ber o
f Sta
tions
Reporting Period
Cumulative Stations
Continuing Outside of ProjectRetired StationsCurrent Project Stations
NREL cdp_fcev_31Created Dec-9-11 9:15 AM
Infrastructure Status: Out of 25 Project Stations, 13 Are Still Operational* (6 outside of DOE project)
Jan-31-2012
2 Online 3 Future
54 Online 15 Future
6 Online
SF Bay Area
DC to New York
3 Online
Detroit Area
Los Angeles Area
16 Online 11 Future
3 mile radius
6 mile radius
12
7
6
**
** Funded by state of CA or others, outside of this project
* CDP station status is as of 9/30/11
10
0
1
2
3
4
5
6
7
8
9
Compressed Liquid Pipeline Reforming Electrolysis
Num
ber o
f Sta
tions
Learning Demonstration Hydrogen Stations by Type
Operating Outside of ProjectOperating Within ProjectHistorical 2005-2009*
NREL cdp_fcev_32Created Dec-9-11 9:15 AM
Delivered On-Site Production
*Some project teams concluded Fall/Winter 2009. Markers show the cumulative stations operated during the 2005-2009 period
Accomplishment: Project Evaluated Many Types of Hydrogen Stations and Made Results Public
Note: Many demonstration stations were taken offline as
planned at conclusion of demo. Some stayed open and/or
received upgrades (CA and NY).
* CDP station status is as of 9/30/11
11
122429
508441
0
100000
200000
300000
400000
500000
600000
0
25000
50000
75000
100000
125000
# Tr
ips
Size
of D
ata
(MB
)
Cumulative On-Road Data Received for Fuel Cell Vehicle Learning Demonstration
MB of data
# trips
Accomplishment: 27 Quarters (7 years) of Data Analyzed to Date, Two New Sets of Composite Data Products Published Since Last AMR
2005 Review
2006 Review
2007 Review
2010 Review
= Composite Data Products Published
Through September 2011: 500,000 individual vehicle trips
122 GB of on-road data 151,000 kg H2 produced/dispensed
3,500,000 miles driven
2008 Review
2011 Review
2012 Review
2004 Review
2009 Review
12
Accomplishment: Total of 99 CDPs Published (40 Winter 2011 CDPs)
Only selected highlights (mostly from the last year) will be covered
13
0 50 100 150 200 250 3000
5
10
Perc
enta
ge o
f Ref
uelin
gs
Distance between refuelings [Miles]2
Distance Driven Between Refuelings: All OEMs
Gen1Gen2After 2009Q4
NREL cdp_fcev_80
1. Some refueling events are not detected/reported due to data noise or incompleteness.2. Distance driven between refuelings is indicative of driver behavior and does not represent the full range of the vehicle.
Gen1 Refuelings1 = 18941 Median distance between refuelings = 56 Miles Gen2 Refuelings1 = 6870 Median distance between refuelings = 81 Miles
Created: Dec-13-11 3:57 PM
Refuelings after 2009Q41 = 9937 Median distance between refuelings = 98 Miles
Accomplishment: Vehicles Show Continued Improvement in Real-World Driving Range
+45% improvement Gen 1 to Gen 2
+75% improvement in real-world driving
range with latest adv. tech. vehicles
Note: Actual range possible >200 miles
2
2
2
14
Sun Mon Tues Wed Thur Fri Sat0
2
4
6
8
10
12
14
16
18
20
Dis
pens
ed H
ydro
gen
[% o
f tot
al]
Day of Week
Dispensed Hydrogen per Day of Week
0
3
6
9
12
15
18
21
24
27
30
Dai
ly A
vera
ge [k
g]
27 kg/day avgAll StationsIndividual Stations
NREL cdp_fcev_83Created: Dec-15-11 1:20 PM
Accomplishment: New Infrastructure CDP Gives Insight Into Specific Fueling Usage Patterns
Several stations are serving >5
vehicles/day on average
Some stations still significantly under- utilized but helping provide coverage Vehicle OEMs state that coverage is
more important right now than capacity
(Data from stations operating after 2009Q4)
15
1 2 3 4 5 6 70
50
100
150
200
250
Station (Sorted By Increasing Station Capacity)
Cap
acity
Util
izat
ion
1 [%]
Demonstration Station Capacity Utilization
58.9%
Maximum Daily Utilization
Maximum Quarterly Utilization2
Average Daily Utilization2
NREL cdp_fcev_91Created: Jan-10-12 11:38 AM
Note: Learning Demonstrationpriority was for good stationcoverage not high station utilization
1Station nameplate capacity reflects a variety of system design consderations including system capacity, throughput, system reliability and durability, and maintenance. Actual daily usage may exceed nameplate capacity.2Maximum quarterly utilization considers all days; average daily utilization considers only days when at least one filling occurred
Accomplishment: While Station Focus is on Coverage, We’ve Tracked Capacity Usage as Baseline for Future
Some stations being utilized 40-60% on
average, and are on path to higher utilization
(Data from stations operating after 2009Q4)
16
Accomplishment: Instantaneous MTBF Improved for 5 of the 7 Sites for the Last 20% of Maintenance Events
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
Shap
e Pa
ram
eter
( β)1
Overall Site Reliability Growth: Infrastructure3
Site: 1 Site: 2 Site: 3 Site: 4 Site: 5 Site: 6 Site: 7
1. IEC 61164:2004(E)., Reliability Growth - Statistical Test and Evaluation Methods, IEC. 2004.
2.% change in instantaneous MTBF
3. Includes data from stations operating after 2009 Q4.
Entire historyLast 20% of eventsFirst 120 Days
NREL cdp_fcev_97Created: Jan-09-12 4:23 PM
Sites Sorted by Increasing Age (Calendar Days)
Failu
re R
ate
Incr
easi
ngFa
ilure
Rat
e D
ecre
asin
g
Instantaneous MTBF improved for 5 of 7 sites for the last 20% of events.
12%2 522%2
43%2
127%2
-64%2 -20%2
379%2
Most stations have shown improved
reliability recently
got better
got better got better got better got better
got worse
got worse
(MTBF = mean time between failure)
(Data from stations operating after 2009Q4)
(Crow-AMSAA Technique)
17
0 200 400 600 800 1000 1200 1400 1600 1800 2000 >20000
5
10
15
20
25Fuel Cell Stack4 Operation Hours
FC S
tack
s [%
]
Operation Hours
25% of FC Stacks > 937 hoursM
edia
n (6
20 h
ours
)
In Service1
Retired2
Not in Service3
NREL cdp_fcev_86Created: Dec-15-11 12:32 PM
1) Stacks that are in service and accumulating operation hours.2) Stacks retired due to low-performance or catastrophic failure.3) Indicates stacks that are no longer accumulating hours either a) temporarily or b) have been retired for non- stack performancerelated issues or c)removed from DOE program.4) Only includes systems operating after 2009Q4.
Accomplishment: Evaluated FC Durability Data from FCEVs After 2009Q4 – Fuel Cell Stack Operation Hours and Max Power Degradation
Some stacks operated over 1,400 hours, but half were still below 600 hours
0
20
40
60
80
100
120
0 100 200 300 400 500 600 700 800 900 10001100120013001400150016001700180019002000Stack Op Hour Segments2
% P
ower
1
Max Fuel Cell Stack3 Power Degradation Over Operation
1) Normalized by fleet median value at 200 hours.2) Each segment point is median FC power (+-50 hrs). Box not drawn if fewer than 3 points in segment.3) Only includes systems operated after 2009Q4.
Data Range25th & 75th PercentilesGroup MedianOutlier
NREL cdp_fcev_90Created: Jan-10-12 10:29 AM
Median power differencefrom 0 hour segment to1300 hour segment = -18.2%
Recent data from stacks shows knee
in FC power degradation curve
at ~200 hours
18
0 300 600 900 1200 1500 1800 2100 2400 2700 3000 >30000102030405060
Fuel Cell Stacks4 Projected Hours to 10% Voltage Degradation
1,74
8
FC S
tack
s [%
]
Time 0 Fit (In Service)Time 0 Fit (Retired or Not in Service)2
Weighted Average (Fleet)
0 300 600 900 1200 1500 1800 2100 2400 2700 3000 >30000102030405060
2,26
1
Projected Hours to 10% Voltage Degradation 1,3
FC S
tack
s [%
]
Steady Operation Fit (In Service)5
Steady Operation Fit (Retired or Not in Service)2, 5Weighted Average (Fleet)
NREL cdp_fcev_87Created: Jan-10-12 10:28 AM
1) Projection using field data, calculated at high stack current, from operation hour 0 or a steady operation period. Projected hours may differ from an OEM's end-of-life criterion and does not address "catastrophic" failure modes.2) Indicates stacks that are no longer accumulating hours either a) temporarily or b) have been retired for non- stack performance related issues or c) removed from DOE program.3) Projected hours limited based on demonstrated hours.4) Only includes systems operating after 2009Q4.5) Not all stacks have a steady operation fit which is calculated from data after 200 hr break-in period. The steady operation starting hour is an approximation of the period after initial break-in where degradation levels to a more steady rate.
Accomplishment: Projected Fuel Stack Durability to 10% Voltage Degradation; Two Fits
Using all data from t0
Fitting after first 200 hours
See technical backup for additional details
in scatter plot
Average projections
Gen 1: 821 Gen 2: 1,062 Recent: 1,748
Many stacks have projections that we
limit to 2X to minimize extrapolation
19
0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 20
100
200
300
400
500
600
700
Avg Fuel Rate (kg/min)
Num
ber o
f Fue
ling
Even
tsHistogram of Fueling Rates
All Light Duty by Year
5 minute fill of5 kg at 350 bar
3 minute fill of5 kg at 350 bar
Year Avg (kg/min) %>1 ------- ----------------- -------2005 0.66 16%2006 0.74 21%2007 0.81 26%2008 0.77 23%2009 0.77 22%2010 0.63 2%2011 0.68 12%
20052006200720082009201020112006 MYPP Tech Val Milestone2012 MYPP Tech Val Milestone
NREL cdp_fcev_52Created: Jan-10-12 11:49 AM
Accomplishment: Tracked Fueling Rates by Year – Analyzed Trends as Stations Move to 700 bar as Standard
Average fueling rate rose, up until 2009 when
some of the higher throughput stations
closed down
20
0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 0
500
1000
1500
2000
2500
Avg Fuel Rate (kg/min)
Histogram of Fueling Rates350 vs 700 bar Fills
5 minute fill of5 kg at 350 bar
3 minute fill of5 kg at 350 bar
Fill Type Avg (kg/min) %>1 Count------------- ------------------ ------- --------Through 2009Q4350 bar 0.82 29% 19659700 bar 0.63 4% 5590------------- ------------------ ------- --------After 2009Q4350 bar 0.70 8% 2594700 bar 0.64 7% 5208
Num
ber o
f Fue
ling
Even
ts (T
hrou
gh 2
009Q
4)
350 bar (Through 2009Q4)700 bar (Through 2009Q4)700 bar (After 2009Q4)350 bar (After 2009Q4)2006 MYPP Tech Val Milestone2012 MYPP Tech Val Milestone
0
100
200
300
400
500
600
700
800
Num
ber o
f Fue
ling
Even
ts (A
fter 2
009Q
4)
NREL cdp_fcev_14Created: Jan-10-12 10:23 AM
Accomplishment: Evaluated Fueling Rates by Fill Pressure and Communication vs. Non-Communication – Shifts Observed During Project
0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 0
500
1000
1500
2000
2500
Avg Fuel Rate (kg/min)
Histogram of Fueling RatesComm vs Non-Comm Fills
5 minute fill of5 kg at 350 bar
3 minute fill of5 kg at 350 bar
Fill Type Avg (kg/min) %>1 ------------- ------------------ -------Through 2009Q4Comm 0.86 30%Non-Comm 0.66 12%------------- ------------------ -------After 2009Q4Comm 0.58 3%Non-Comm 0.81 16%
Num
ber o
f Fue
ling
Even
ts (T
hrou
gh 2
009Q
4)
Comm (Through 2009Q4)Non-Comm (Through 2009Q4)Non-Comm (After 2009Q4)Comm (After 2009Q4)2006 MYPP Tech Val Milestone2012 MYPP Tech Val Milestone
0
100
200
300
400
500
600
700
800
Num
ber o
f Fue
ling
Even
ts (A
fter 2
009Q
4)
NREL cdp_fcev_29Created: Jan-10-12 10:28 AM
700 bar fueling rates holding constant at ~0.63 kg/min
350 bar fueling rates dropped
from 0.82 to 0.70 kg/min
Comm. fill rates dropped while non-comm. fill rates increased
350 vs. 700 bar
Communication vs. non-communication
Fueling rates are still evolving due changes in technology and protocols
21
Accomplishment: Leveraged Effort to Other Fuel Cell Applications; Cross-Application CDPs Expanding
Accomplishment: Significant leveraging of
this project to other evaluations
(e.g., ARRA/DOD: MHE, backup power)
Fueling rates vary by application, driven by constraints on nominal pressure,
volume, tank materials
22
Accomplishment: Analysis Results Informed R&D Activities and Codes and Standards Development
-20 0 20 40 60-20
-10
0
10
20
30
40
50
60
Ambient Air Temperature [deg C]
Tank
Tem
pera
ture
[deg
C]
Tank vs. Ambient Air Temps Prior to Refueling
Freq
uenc
y
50
100
150
200
250
300
-40 -20 0 20 400
500
1000
1500
2000
Delta Temperature [deg C]
Cou
nt
Delta Temperature: Tank minus Ambient
Delta Temp HistogramNormal Distribution Fit
0
0.02
0.04
0.06
0.08
Den
sity
Mean= -3.751Std Dev= 6.129
NREL CDP72Created: Mar-11-10 10:24 AM
-This CDP created in support of SAE J2601 related to refueling-Temperatures are prior to refueling and exclude data within 4 hours of a previous fill-The plot to the left excludes ambient temperatures less than -5 deg C
FCEVs arrive at station with a tank temperature
that is 3.8 degrees C colder than ambient
temp
This result allowed participants in J2601 to use validated/realistic
initial conditions to their computer models for tank
temperature rise
23
Accomplishment: Communicated Final Project Results to Broad Audience via Multiple Paths
• Draft final report completed in March
• Final report published in April and posted on NREL’s web site
• Published EVS-26 paper for Los Angeles conference
• Held public webinar o 260 participants (400
registered) o Active Q&A
• Created more interactive way to access CDP results from web site
Link to sunburst
24
Highlights of Interactions and Collaborations
• Auto/Energy Industry Partners o Detailed discussion of NREL results and methodology o Discussion of voltage degradation calculations; discussions of how to
do new/previous CDPs with fewer teams o Review of all results prior to publication
• U.S. DRIVE Technical Teams o Hydrogen Storage and Fuel Cell Tech Team Briefings Annually
• FCHEA Technical Working Groups o Transportation Working Group o Joint H2 Quality Task Force
• California Organizations o CaFCP and CHBC: NREL actively participating as member o CARB and CEC: New stations offer potential to provide future data to
NREL • Early FC Market Evaluations: DOD and ARRA
o Leveraged experience to evaluate FC forklifts, backup, and stationary power; begun analyzing PHVs for OEM
25
Future Work • Remainder of FY12:
o Support DOE in launching new vehicle evaluation project – “Light-Duty Fuel Cell Electric Vehicle Validation Data” (FOA 625)
o Outside of this project (but related) – Transition H2 station analysis activity to new AOP activity “Next Generation
H2 Station Analysis” led by Sam Sprik (see poster TV017 for more info.) – Support DOE in launching new infrastructure validation project: “Validation
of Hydrogen Refueling Station Performance” (FOA 626, topic 1) • FY13:
o This project (Learning Demo) will conclude in FY12, so this project will not continue into FY13
o However, two separate projects on FC vehicles and H2 infrastructure validation will exist in FY13 (referenced above)
o Continue to leverage analysis capability to other validations o Identify and exploit new opportunities to document FC & H2
progress publicly
26
Summary • Relevance
o Provided DOE and taxpayers strong return on investment made in this 7-year project, the largest single FCEV & infrastructure demonstration in the world to date
o Many system-level DOE program targets validated by this project
• Approach o Collaborative relationship to analysis with industry partners o Established core HSDC and analysis capability and tools o This project is the 1st time such comprehensive data was collected by an independent
3rd-party and consolidated for public dissemination
• Technical Accomplishments and Progress o 99 total CDP analysis results available (14 more than at last AMR); publication at
conferences every 6 months o Project achieved the two key technical targets on driving range (>250 miles) and FC
durability (>2,000 hours) [refer to technical backup slides and Final Report]
• Collaborations o Worked closely with industry partners to validate methodology, and with other key
stakeholders to ensure relevance of results
• Future Work o Support launch of new technology validation projects, including new opportunities to
objectively evaluate status of H2 & FC technology and other vehicle technology o HSDC and analysis capability will continue to be used on future projects
183 Vehicles: 154,000 hours, 3.5M miles, 500K trips 25 Stations: 151,000 kg produced/dispensed, 33K fuelings
27
Questions and Discussion
All public Learning Demo papers and presentations are available online at http://www.nrel.gov/hydrogen/proj_tech_validation.html
Project Contact: Keith Wipke, National Renewable Energy Lab 303.275.4451 keith.wipke nrel.gov @
Technical Backup Slides
29
0 500 1000 1500 20000
500
1000
1500
2000
2500
3000
3500Comparison of Operation Hours and Projected Hours to 10% Voltage Degradation5
Proj
ecte
d H
ours
1,2,
4
Operation Hours
projected hrs = operation hrs
FC SystemFC System (Limited)2
FC System (Retired)3
Unity Line
NREL cdp_fcev_88Created: Jan-10-12 10:29 AM
25% of stacks arebelow the unity lineand have operatedpast 10% voltagedegradation.
On average, thesestacks haveoperated for 990hours.
Stacks above theunity line have notoperated past 10%voltage degradation.
1) Indicates the projected hours to a 10% voltage degradation based upon curve fitting data from operation hour 0.2) Projected hours limited based on demonstrated hours.3) Stacks retired due to low-performance or catastrophic failure.4) Each projection has uncertainty based on the confidence intervals of the fit.5) Only includes systems operated after 2009Q4.
Accomplishment: Scatter Plot of Fuel Cell Operation Hours and Projected Hours to 10% Voltage Degradation
Many stacks have projections that we
limit to 2X to minimize extrapolation
Stacks consistently operating past 10% voltage degradation
30
Project Achieved Both Technical Goals; Outside Analysis Used for Cost Evaluation (updated since 2011 AMR in blue)
Vehicle Performance Metrics Gen 1 Vehicle Gen 2 Vehicle 2009 Target After 2009Q4
Fuel Cell Stack Durability 2,000 hours
Max Team Projected Hours to 10% Voltage Degradation 1,807 hours 2,521 hours --
Average Fuel Cell Durability Projection 821 hours 1,062 hours 1,748 hours
Max Hours of Operation by a Single FC Stack to Date 2,375 hours 1,261 hours 1,582 hours
Driving Range 250 miles
Adjusted Dyno (Window Sticker) Range 103-190 miles 196-254 miles --
Median On-Road Distance Between Fuelings 56 miles 81 miles 98 miles
Fuel Economy (Window Sticker) 42 – 57 mi/kg 43 – 58 mi/kg no target --
Fuel Cell Efficiency at ¼ Power 51 – 58% 53 – 59% 60% --
Fuel Cell Efficiency at Full Power 30 – 54% 42 – 53% 50% --
Infrastructure Performance Metrics 2009 Target After 2009Q4
H2 Cost at Station (early market)
On-site natural gas reformation
$7.70 – $10.30/kg
On-site Electrolysis
$10.00 – $12.90/kg
$3/gge --
Average H2 Fueling Rate 0.77 kg/min 1.0 kg/min 0.65 kg/min
Outside of this project, DOE independent panels concluded at 500 replicate stations/year: Distributed natural gas reformation at 1500 kg/day: $2.75-$3.50/kg (2006) Distributed electrolysis at 1500kg/day: $4.90-$5.70 (2009)
Outside review panel
31
1) FC Durability Target of 2000 Hours Met By Gen 2 Projections (2010 AMR)
Gen1 Gen2 Gen1 Gen2 Gen1 Gen20200400600800
1000120014001600180020002200240026002800
2006 Target
2009 Target
Actual Operating Hours Accumulated To-Date Projected Hours to 10% Voltage Degradation
Tim
e (H
ours
)
DOE Learning Demonstration Fuel Cell Stack Durability:Based on Data Through 2009 Q2
Max Hrs Accumulated1,2 Avg Hrs Accumulated1,3 Projection to 10% Voltage Degradation4,5,6
Max ProjectionAvg Projection
NREL CDP01Created: Mar-23-10 10:39 AM
(1) Range bars created using one data point for each OEM. Some stacks have accumulated hours beyond 10% voltage degradation.(2) Range (highest and lowest) of the maximum operating hours accumulated to-date of any OEM's individual stack in "real-world" operation.(3) Range (highest and lowest) of the average operating hours accumulated to-date of all stacks in each OEM's fleet.(4) Projection using on-road data -- degradation calculated at high stack current. This criterion is used for assessing progress against DOE targets, may differ from OEM's end-of-life criterion, and does not address "catastrophic" failure modes, such as membrane failure.(5) Using one nominal projection per OEM: "Max Projection" = highest nominal projection, "Avg Projection" = average nominal projection. The shaded projection bars represents an engineering judgment of the uncertainty on the "Avg Projection" due to data and methodology limitations. Projections will change as additional data are accumulated.(6) Projection method was modified beginning with 2009 Q2 data, includes an upper projection limit based on demonstrated op hours.
*
Durability is defined by DOE as projected hours to 10% voltage degradation *
32
Dyno Range (2) Window-Sticker Range (3) On-Road Range (4)(5)0
50
100
150
200
250
300
Vehi
cle
Ran
ge (m
iles)
Vehicle Range1
2015 Target2009 Target Gen 1 Gen 2
NREL CDP02Created: Mar-10-10 1:18 PM
(1) Range is based on fuel economy and usable hydrogen on-board the vehicle. One data point for each make/model.(2) Fuel economy from unadjusted combined City/Hwy per DRAFT SAE J2572.(3) Fuel economy from EPA Adjusted combined City/Hwy (0.78 x Hwy, 0.9 x City).(4) Excludes trips < 1 mile. One data point for on-road fleet average of each make/model.(5) Fuel economy calculated from on-road fuel cell stack current or mass flow readings.
2) Vehicle Range Achieved 2009 Target of 250 Miles with Gen 2 Adjusted Fuel Economy (2010 AMR)
33
0
2
4
6
8
10
12
14
16Projected Early Market 1500 kg/day Hydrogen Cost1
$/kg
Natural Gas Reforming2 Electrolysis2
2015 DOE Hydrogen Program Goal Range3
Median25th & 75th Percentile10th & 90th Percentile
Created: Jan-19-10 11:08 AM
(1) Reported hydrogen costs are based on estimates of key cost elements from Learning Demonstration energy company partners and represent thecost of producing hydrogen on-site at the fueling station, using either natural gas reformation or water electrolysis, dispensed to the vehicle. Costsreflect an assessment of hydrogen production technologies, not an assessment of hydrogen market demand.(2) Hydrogen production costs for 1500 kg/day stations developed using DOE’s H2A Production model, version 2.1. Cost modeling represents thelifetime cost of producing hydrogen at fueling stations installed during an early market rollout of hydrogen infrastructure and are not reflective of thecosts that might be seen in a fully mature market for hydrogen installations. Modeling uses default H2A Production model inputs supplemented withfeedback from Learning Demonstration energy company partners, based on their experience operating on-site hydrogen production stations. H2A-based Monte Carlo simulations (2,000 trials) were completed for both natural gas reforming and electrolysis stations using default H2A values and10th percentile to 90th percentile estimated ranges for key cost parameters as shown in the table. Capacity utilization range is based on the capabilitiesof the production technologies and could be significantly lower if there is inadequate demand for hydrogen.(3) DOE has a hydrogen cost goal of $2-$3/kg for future (2015) 1500 kg/day hydrogen production stations installed at a rate of 500 stations per year.
Key H2 Cost Elements and Ranges
Input Parameter Minimum (P10)
Maximum (P90)
Facility Direct Capital Cost $10M $25M
Facility Capacity Utilization 85% 95%
Annual Maintenance & Repairs $150K $600K
Annual Other O&M $100K $200K
Annual Facility Land Rent $50K $200K
Natural Gas Prod. Efficiency (LHV) 65% 75%
Electrolysis Prod. Efficiency (LHV) 35% 62%
NREL CDP15
3) Projected Early Market H2 Production Cost from Learning Demo Energy Partners’ Inputs (2010 AMR)
*
*
This project provides an excellent learning opportunity, but stations were not meant to emulate high volume replicate
stations of the future. Permitting was in transition.
Outside of this project, DOE independent panels concluded at 500 replicate stations/year: Distributed natural gas reformation at 1500 kg/day: $2.75-$3.50/kg (2006)
Distributed electrolysis at 1500kg/day: $4.90-$5.70 (2009)
Reviewer-Only Slides
35
Responses to Previous Year (FY11) Reviewers’ Comments
• Q: “The project is nearly finished, and future work should focus on effectively disseminating information to key automotive decision makers”
• A: We have communicated results very broadly this year, as discussed in this presentation, including the webinar, EVS-26 paper, final report, and website.
• Q: “It is hoped that DOE will be able to continue funding technology validation projects at NREL” and “The project should continue in some form. Future years will be critically important as FCVs approach commercialization. Reliable and accurate data will be required for continued technology development.”
• A: DOE continues to support technology validation projects at NREL beyond this Learning Demonstration project conclusion. DOE has recently announced two FOAs (625 and 626) that will provide data to NREL on FCEVs and H2 stations for analysis. NREL will also continue validation of FC buses, FC MHE, FC backup power, FC stationary power, and Wind2H2.
• Q: “More information on the reasons vehicles are retired from the database would be helpful. Also, more information on the power drop off at 350 bar would be appreciated.”
• A: Vehicles are retired from the database for many reasons, including: contracts ending, vehicles being redeployed outside of the DOE project, traffic accidents, degradation or failure on both FC and non FC systems (e.g. batteries). The 2nd question is not clear what is being asked: FC power is not a function of tank pressure.
• Q: “Researchers should add analysis of material handling equipment to the NREL
portfolio” • A: FC MHE analysis was added to NREL’s portfolio in late 2009. See Jen Kurtz’
(ARRA) and Todd Ramsden’s (Oorja) AMR presentations in 2011 and 2012.
36
Publications and Presentations (Since FY11 AMR, newest to oldest, key text in bold)
1. Wipke, K., Sprik, S., Kurtz, J., Ramsden, T., Ainscough, C., Saur, G., “Final Results from U.S. FCEV Learning Demonstration,” 26th International Battery, Hybrid and Fuel Cell Electric Vehicle Symposium (EVS-26), Los Angeles, CA, May 2012. (paper and presentation)
2. Wipke, K., Sprik, S., Kurtz, J., Ramsden, T., Ainscough, C., Saur, G., “National Fuel Cell Electric Vehicle Learning Demonstration Final Report,” NREL Technical Publication, Golden, CO, April 2012. (paper)
3. Kurtz, J., Wipke, K., Eudy, L., Sprik, S., Ramsden, T., “Fuel Cell Technology Demonstrations and Data Analysis,” Chapter in Hydrogen Energy and Vehicle Systems, Green Chemistry and Chemical Engineering, CRC Press, April 2012. (book chapter)
4. Wipke, K., Sprik, S., Kurtz, J., Ramsden, T., Ainscough, C., Saur, G., “National Hydrogen Learning Demonstration Status,” DOE's Informational Webinar Series, February 2012. (presentation and webinar recording)
5. Wipke, K., Sprik, S., Kurtz, J., Ramsden, T., Ainscough, C., Saur, G., “Winter 2011 – All Composite Data Products: National FCEV Learning Demonstration, with Updates through January 18, 2012,” Golden, CO: National Renewable Energy Laboratory, published January 2012. (presentation)
6. Wipke, K., Sprik, S., Kurtz, J., Ramsden, T., Ainscough, C., Saur, G., 2011 Annual Progress Report for NREL's "Controlled Hydrogen Fleet and Infrastructure Analysis Project,“ November 2011). (paper)
7. Wipke, K., Sprik, S., Kurtz, J., Ramsden, T., Ainscough, C., Saur, G., “Conclusion of the National FCEV Learning Demonstration Project,” presented at the Fuel Cell Seminar, Orlando, Florida in November 2011. (presentation)
8. Wipke, K., Sprik, S., Kurtz, J., Ramsden, T., Ainscough, C., Saur, G., “Fall 2011 – All Composite Data Products with Updates through October 5, 2011: National FCEV Learning Demonstration,” Golden, CO: National Renewable Energy Laboratory, published October 2011. (presentation)
9. Sprik, S., Kurtz, J., Wipke, K., Ramsden, T., Ainscough, C., Eudy, L., and Saur, G., “Real-World Hydrogen Technology Validation”, International Conference on Hydrogen Safety (ICHS 2011), September 2011. (presentation and paper)