London Hydrogen Partnership Stationary Hydrogen and FuelCell Showcase
1. STATIONARY
HYDROGEN & FUEL CELL
SHOWCASE
7TH MARCH 2012, LONDON, CITY HALL
ITM POWER DESIGNS
AND MANUFACTURES
HYDROGEN ENERGY SYSTEMS
FOR ENERGY STORAGE AND
CLEAN FUEL PRODUCTION
2. STATIONARY
HYDROGEN & FUEL CELL
SHOWCASE
7TH MARCH 2012, LONDON, CITY HALL
Contents
• Positioning
• Sector offering
• Remote Power ITM POWER DESIGNS
• Hydrogen Home AND MANUFACTURES
• Summmary HYDROGEN ENERGY SYSTEMS
FOR ENERGY STORAGE AND
CLEAN FUEL PRODUCTION
4. THE CHALLENGE
Electricity cannot be easily stored
• Renewable power cannot be scheduled
• Balancing supply and demand
• Required at small & large scale
• Energy storage required for long periods
• Represents major barrier to adoption of renewables
POSITIONING
ENERGY STORAGE | CLEAN FUEL
5. ENERGY STORAGE SYSTEMS
Grid | Grid Supported | Off Grid
• Grid connected Energy system complexity
• Grid tied back up power
• Grid supported primary power
• Off grid
SYSTEM COMPLEXITY
HYDROGEN ENERGY SYSTEMS
6. WHY REMOTE | OFF GRID?
Grid connection charges | Cost of cables
• Grid connection charges
• Cost of cables; planning timescales
• Plays to the strengths of hydrogen energy storage
REMOTE POWER
HYDROGEN ENERGY SYSTEMS
7. ULTIMATE ES CHALLENGE
The ultimate balancing challenge
• Remote Power: Pure energy storage
• Hydrogen Home: Power | Heat | Fuel
SYSTEM COMPLEXITY
HYDROGEN ENERGY SYSTEMS
11. SITE SURVEYS
Site Location: Funshog, Co. Meath
• 60 km north of Dublin,15 km inland
• 53°48’42” N, -6°29’17” E
SITE SURVEY
ENERGY STORAGE | CLEAN FUEL
12. POWER INPUTS
Wind and solar resource study
• Use location data
• Use measured data
SITE RESOURCES
ENERGY STORAGE | CLEAN FUEL
13. TELECOMS POWER SYSTEM DESIGN LOGIC
Input Subsystem Output Logic
Telecoms 1. Primary loads FC capacity • Supply load without drawing from battery
Peripherals Wind
• Net capacity typically 5-10x average load
capacity
2. Primary power • Reliability more important than utilisation
Local • Balanced mix uneconomic in many areas
PV rating
resource
3a. Seasonal
Tank size • Maintain battery >80% year-round
Capacity storage
factor
Electrolyser • 1,000 – 1,500 hrs operation pa
Economics rating • Large enough to prevent battery overheat
3b. Daily Battery • Maintain battery >80% SoC year-round
storage capacity • Large enough to absorb supply peaks
DESIGN LOGIC
ENERGY STORAGE | CLEAN FUEL
15. ENERGY SYSTEMS MODELING RESULTS
Wind and solar resource study
• Hybrid ES system
• Lowest cost
• Highest security
MODELING RESULTS
ENERGY STORAGE | CLEAN FUEL
17. HHOME STRATEGY
Energy led housing design
• 2016 legislation is energy driven
• Design the energy system first
• Start with off grid and work forwards
• Extend scenarios to existing housing
• Develop the legislative framework
HYDROGEN HOME ENERGY SYSTEM
POWER | HEAT | FUEL
18. HHOME STRATEGY
Energy led housing design
Hydrogen Cooking Backup Power Seasonal Storage Full Autonomy (Off Grid)
Increased Hydrogen Use
Increased Storage Requirements
Increased buildings-integrated renewables
HYDROGEN HOME ENERGY SYSTEM
POWER | HEAT | FUEL
19. ENERGY SYSTEMS MODELING RESULTS
Off Grid homes
• The ultimate challenge
• Energy storage and renewable heat
HYDROGEN HOME ENERGY SYSTEM
POWER | HEAT | FUEL
20. ENERGY SYSTEMS MODELING RESULTS
Off Grid homes
• The ultimate challenge
• Energy storage and renewable heat
HYDROGEN HOME ENERGY SYSTEM
POWER | HEAT | FUEL
21. H2HOME SCHEME
Off Grid to Retro Fit
• Code 6
• Off grid
• Eco village
• Retro Fit
HYDROGEN HOME ENERGY SYSTEM
POWER | HEAT | FUEL
22. H2HOME SCHEME: ECOISLAND
Off Grid to Retro Fit
• Code 6
• Off grid
• Eco village
• Retro Fit
HYDROGEN HOME ENERGY SYSTEM
POWER | HEAT | FUEL