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Fuel Cells An Emerging High-Technology Industry

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Energy Sets the Scene. Setting the Scene for Fuel Cells: ... Stark State College of Technology Dorey Diab. Hocking College. Catacel Bill Whittenberger ... – PowerPoint PPT presentation

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Title: Fuel Cells An Emerging High-Technology Industry


1
Fuel Cells An Emerging High-Technology Industry
  • Rodger McKain, PhD
  • 4/22/2006

2
Energy Sets the Scene
3
Setting the Scene for Fuel Cells Petroleum
supply, consumption, and imports, 1970-2025
(million barrels per day)
13 million Bbls/d
US EIA 2005
4
Setting the Scene for Fuel Cells Petroleum
supply, consumption, and imports, 1970-2025
(million barrels per day)
60
71
US EIA 2005
5
Primary energy use by fuel, 2003-2025
(quadrillion Btu)
1 quad 170 million bbls 1 trillion SCF (nat
gas) 45 million tons (coal)
6
Fuel Cells An Old Technology Provides New
Solutions
7
First Communication of Fuel Cell Related Phenomena
  • I cannot but regard the experiment as an
    important one
  • William Grove to Michael Faraday
  • October 22, 1842

8
SOFC Fuel Cell Operation
2 H O2- H2O 2 e-

External electrical conducting circuit
2e-
H2
H2O 2 e-
O2-
O2
2O2-
½ O 2 2 e-
H2 2 H 2e-
Porous perovskite cathode
Porous nickel-cermet anode
Solid Oxide Electrolyte ionic conducting
membrane
9
Fuel Cell Operation
H2 ½ O2 H2O
H2O
O 2e_ O
H2 O _ 2e_ H2O
(Ionic transport)
Source U.S. Fuel Cell Council
10
Attributes of Fuel Cells
AFC PACF PEM
MCFC SOFC Electrolyte KOH
Phosphoric Sulfonic Molten Y2O3-ZrO2
Acid Acid Carbonate Ceramic
Polymer Salt Temperature 100
0C 2000C 80 0C
6500C 800-10000C Fuel H2 H2
H2 H2/CO H2/CO Efficiency (H2
fuel) 60 55 60 55
55 (NG fuel) --
40 35 50
50 Pollution Low Low
Low Low Low Hydrocarbon No
Difficult Difficult
Yes Yes Fuel Use Start-Up Fast
Moderate Fast Slow
Slow
Zirconia
11
Fuel Cell Power System
12
(No Transcript)
13
Fuel Cell Impact (from Hydrogen Economy
Statements)
  • Clean environment
  • Reduced Global Warming
  • Energy independence
  • National Infrastructure Security
  • Low cost, reliable electrical power

14
Regulated Emissions ComparisonCoal Fired
Utility vs. PA Fuel Cell
Contaminant Average U.S. Utility Emissions (lbs per megawatt-hour) ONSI PC25 200 kW NG Fuel Cell (lbs per megawatt-hour)
Nitrogen Oxides 7.65 0.016
Carbon monoxide 0.34 0.023
Reactive organic gases 0.34 0.0004
Sulfur oxides 16.1 0
Particulates (PM10) 0.46 0
15
Fuel Cell System Trends Compared with other
Distributed Generation Technologies
70
Combined Cycle
60
Carbonate Fuel Cell
Solid Oxide Fuel Cells
50
PAFC
Aero Gas Turbines
40
Electrical Generation Efficiency LHV
PEM Fuel Cell
30
Industrial Gas Turbine
20
IC Engines
Stirling Engine
10
Microturbines
0
1
10
100
1,000
10,000
100,000
500,000
Residential
Commercial
Industrial
Wholesale
Size in kW
16
Hydrogen Production
  • Principle Sources of Hydrogen
  • Hydrocarbons (natural gas and crude oil)
  • Water
  • Conversion Technology
  • Steam Methane Reforming (commercial)
  • Water Electrolysis (commercial)
  • Methane Pyrolysis (small scale)
  • Water-Sulfur-Iodide Process (small scale)

17
Hydrogen Production Dilemma
  • 13 million barrels crude oil per day used in
    transportation equivalent to 1.46 billion
    pounds per day hydrogen
  • This would require doubling the total US power
    production (850 GWe to 1780 GWe) if hydrogen were
    produced by conventional electrolysis. (assume 1
    MW per 1000 lbs and efficiency improvements)
  • OR
  • This would require 23 trillion cubic feet of
    natural gas per year - approximately 110 of the
    2002 total US consumption, nearly doubling the
    total natural gas requirement.

18
Hydrogen Production Solutions
  • Near Term (small volumes)
  • Conventional technology distributed to point of
    use
  • Fueling stations (hydrocarbon reforming or water
    electrolysis)
  • Long Term (large volumes)
  • High Temperature gas Cooled Nuclear Reactor
    boost electrolysis efficiency from 20 to 40.
    (Reduce power requirement by half)
  • FutureGen Hydrogen and power from coal
  • Solar Cell Direct Electrolysis

19
Are Fuel Cell Powered Cars Really More Efficient?
40
100 Energy Units
IC Engine 40
Power Train 37.5
15
Conventional Car
60
20 Idling
5 Friction
- 60 Units H2 production
20
40 Energy Units
Fuel Cell 50
Direct Drive 75
15
Fuel Cell Car
20
0 Idling
5 Friction
20
Technology Commercialization Conundrum
  • Public Expectations are high
  • But, Success Rates are less than 30
  • And, Success generally takes longer and costs
    more
  • Fuel Cell system OEMs will determine the
    future
  • Much more investment is required
  • Development phase is more costly than
    anticipated
  • Strategic development is likely to dominate
  • But, focus is on suppliers and entrepreneurs
  • Basis for a hard, clear-eyed review of the fuel
    cell opportunity
  • Role of OEMs
  • Public expectations
  • Government and NPO involvement

21
When Will Fuel Cells Be Available?(An Ohio View)
Source Projections represent Taratec
Corporations estimate of market activitybased
on input from industry analysts and information
provided in executive interviews.
22
Todays Technology Cost Comparison
  • Watts Sector
    Application /kW
  • 0.1 1.0 Biomedical
    Autonomous power for 105

  • sensors and implants
  • 1 100 Electronics
    Battery replacement 104
  • 100 - 10,000 Communications Battery
    replacement 103 104

  • Cell tower stationary power
  • 5,000 - Transportation
    Propulsion 101
    102
  • 100,000
    Auxiliary Power Units
  • gt 10,000 Stationary power Emergency
    backup 102 103

  • grid supplement

23
Market Projections
Portable Power leads the way
Military/Aerospace
Vehicle
Stationary
Auxiliary
Portable
24
Public Expectations
  • Set by soft industry successes
  • Dominated by services sector and incremental
    changes to existing businesses
  • Low development costs
  • Investment usually for revenue growth
  • Less than 5 years for acceptable ROI
  • Satisfying unmet market needs (existing markets)
  • Returns through MAs or IPOs
  • Not universally applicable

25
Market Penetration (Per Cent Households)
Time to Max. TV 30 yrs Color TV 10
yrs Electricity 75 yrs Automobile 80
yrs Telephone 90 yrs Cell phone 20 yrs PC
20 yrs Internet 15 yrs
26
Fuel Cell vs. Service Sector Commercialization
  • Some Fuel Cells are here today
  • Battery replacement
  • Military
  • Space Shuttle
  • Back-up power
  • But, to impact domestic energy consumption
  • FCs require
  • 10-100X development funding 100-200 million per
    product (from now)
  • 10X development time (20 yrs)
  • But, FCs offer similar market opportunities (20
    billion) to service sector businesses

27
Fuel Cell Commercialization
Cost Comparison
Fuel Cells
Log
Service Sector
Log yrs
28
Service Sector vs. Fuel Cell Commercialization
2000
Service
Fuel Cells
DCF ( million )
0
Yrs from 2006
20
10
-200
  • Differentiators
  • Infrastructure
  • Capital intensity
  • Market Creation
  • Diversity
  • Competitive Alternatives

29
Fuel Cell Cost Pyramid (DOE)
Cost Contribution /kW
Industrial Segments
Now
Future
Balance of Plant Packaging, Air/Fuel Handling
46
6
44
12
Controls/Power Electronics Inverter, DC Boost,
Sensors, Actuators
128
19
110
28
27
Hot Box Reformer, Recuperator Manifold,
Filter, enclosure/insulation
184
109
28
Stack
325
48
118
30
683
382
30
Fuel Cell Business Creation Gap
  • This time around----20-year development cycle
    (profitable industry following silicon chip
    history)
  • Suppliers betting on system integrators
  • System integrators require large infusions of
    capital to advance to product stagethe
    bottleneck in the cycle...returns are still
    beyond the horizon.
  • Gap Financing development for an uncertain
    market.

31
Fuel Cells? 2005-2060
32
FCs Early Adopter Chasm (Created by Government
Development Programs)
  • Early demand for components
  • OEMs commercial development
  • lags demonstration gov programs
  • Transition to commercial prototypes
  • Renewed demand as OEMs
  • book product sales

Revenue Chasm
DCF
Years
33
How does a fuel cell business survive and thrive?
  • Military bootstrap
  • Federal agency funding
  • Private investors
  • Strategic partners/customers
  • Leveraging Resources

34
Building an Industry
  • General Requirements
  • Source(s) of ideas
  • Availability of funds
  • Accessible Workforce
  • Education and Training Resources
  • Informed and supportive infrastructure
  • Competitive business environment
  • Regulations, Taxation, Financing etc.

35
Critical Role for Building a Fuel Cell Industry
in Ohio
  • Educate Policymakers
  • Create realistic expectations
  • Facilitate information exchange
  • Inform the public
  • Engage all interests
  • Create opportunities
  • Focus on government-University-Industry
    Relationships
  • Maintain an independent perspective
  • Enable new and existing companies to access
    resources to pursue fuel cell business plans more
    aggressively in Ohio than anywhere else

36
Fuel Cells for 2010Todays Glimpse into the
Future
37
Motive Power
38
Motive Power
39
Auxiliary Power
40
Fueling Stations
41
Small-Scale Power Systems
42
Concept Truck Auxiliary Power Units Save 700
Million Gallons Diesel Fuel per Year
  • Long-haul trucks idle about 2,000 hours per year
  • Idling trucks consume 860 Millions gallons of
    fuel per year!
  • Fuel cells can reduce truck idling fuel
    consumption from 1 gal/hr to 0.2 gal/hr or by 688
    million gallons.

43
Concepts Aircraft Power Systems
  • Benefits to commercial aircraft cabin power
  • 50 fuel savings over conventional turbine APU
  • Reduced emissions (e.g., gt20 NOx reduction)
  • Reduced noise (gt10db reduction at gate)

Commercial Aircraft
  • Benefits to UAVs
  • Emergency power improved vehicle recovery
  • Payload power significant increase in payload

Unmanned Aerial Vehicle
  • Benefits to HALE UAVs
  • Longer mission endurance
  • Higher payloads

NASA LEAP Project (Low Emissions Alternative
Power)
High-Altitude, Long Endurance UAV
44
Todays Designs Tomorrows Products
45
Summary
46
The Fuel Cell Opportunity
  • High efficiency Energy
    Independence
  • Low regulated emissions
  • Quiet
  • Fuel flexibility
  • High quality power
  • High reliability Energy
    Security
  • Widespread applications (transportation, power,
    medical, communications, military, aerospace,
    electronics)
  • IF lt400/kW
    stationary power
  • lt35/kW
    automotive
  • New industry (250 billion per year)

47
Challenges for Widespread Use of Fuel Cells
  • Cost (capital and operating) further
    breakthroughs?
  • Operating Life 4000 40,000 hours (automotive
    vs. stationary power)
  • Reliability
  • Investment Catch 22?
  • Many demonstrations
  • Hydrogen Infrastructure (fuel transportation and
    storage)
  • Codes and Standards

48
Fuel Cell Types
Source U.S. Fuel Cell Council
49
The Ohio Fuel Cell Enterprise
  • Ohio Fuel Cell Coalition Ken Alfred
  • Wright Fuel Cell Group John McGrath
  • NorTech Dorothy Baunach
  • CWRU Bob Savinell, Tom Zawodzinski
  • OSU Giorgio Rizzoni
  • CSU Orhan Talu
  • U of Toledo Martin Abraham
  • U of Akron Steven Chuang
  • Ohio University Dave Bayless
  • NASA Glen Serene Farmer
  • Wright Patterson AFRL Tom Reitz
  • Battelle Dave Salay
  • EMTEC Frank Svet, Mike Martin
  • EWI Frank Jacob
  • Stark State College of Technology Dorey Diab
  • Hocking College
  • Catacel Bill Whittenberger
  • MetaMateria Partners Dick Schorr
  • NexTech Materials Bill Dawson
  • SOFCo-EFS Rodger McKain
  • TMI Benson Lee
  • Parker-Hannifin
  • AEP
  • First Energy
  • Dana Corporation
  • Rockwell International
  • Keithley Instruments
  • Solarflo
  • Vanner
  • Governor Bob Taft
  • Ohio Department of Development Pat Valente,
    Mike McKay
  • Stark County Development Board Steve Paquette
  • Congressman Regula

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