Green Hydrogen and Power to X - Transport and Climate ......Green Hydrogen and Power to X Silver...
Transcript of Green Hydrogen and Power to X - Transport and Climate ......Green Hydrogen and Power to X Silver...
Green Hydrogen and Power to X Silver Bullet for Decarbonizing Transport?Lecture at TCCW 2020Wednesday, 4th March 2020, 2 – 3pm
Charlotte Hussy & Heino von Meyer
International PtX Hub – BerlinCatalysing green hydrogen solutions on a global scale
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Clip explaining Power-to-X can be found online:
https://www.changing-transport.org/video-power-to-x-
how-does-it-work/
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Why Power to X in transport?
96 % Fossil fuels
Global
energy
related
CO2
emissions
CO2 emissions in transport
The transport sector still heavily depends on fossil fuels and cannot be electrified directly.
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Transport energy use by fuel type
Source: IEA (2017); ITF (2017); Irena, IEA, & Ren21 (2018).
24% Transport
11.8 % Surface Passenger Transport
6.6% Surface Freight
5.2 % Aviation & Shipping
1.0% Non-renewable
electricity
3.1%Renewable
energy
1.2% Biofuels
0.3% Renewable
electricity
0.01% Biomethane
1.6% Ethanol
The transport sector is testing and investing in hydrogen and Power to X systems
5Source: Amelang (2018); Hill (2020); Kanter (2013); Ohnsman (2019); Pico (2020); U.S. Air Force (2006).
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How does it work – Power to X?
Power to X is the conversion of electric power to other forms of energy carriers for use in different sectors
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Hydrogen Electrolysis
Renewable
Power
Generation
O2 H2
Power to Fuels
Power to Hydrogen
Power Generation Applications / SectorsRessources / Conversion
H2O
Carbon Capture
Direct air capture, biomass or
flue gases
CO2
Example: PtX for fuel production in Germany and The Netherlands
8Source: KIT (2019); Zenid & Climeworks (2020).
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How to use Power to X in transport?
Internal combustion
engine with PtX
How efficient would you rate the three different technology options?
10Source: based on Agora Verkehrswende (2018).
%
Battery-electric PtX
Renewable power
100%
Renewable power
100%
Renewable power
100%
Fuel cell H2
Overall efficiency
%
Overall efficiency
%
Overall efficiency
%
? ? ?
Please take part at the short survey:
- www.menti.com; digit code 77 10 85
Link to results
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Internal combustion
engine with PtX
Source: based on Agora Verkehrswende (2018).
%
Battery-electric
vehiclesPtX
Renewable power
100%
Battery use 86%
69%
Renewable power
100%
Renewable power
100%
Hydrogen
67%
Hydrogen
67%
Electricity
32%
Liquid fuel
44%
26% 13%
Transmission Transmission Transmission(Dis-)charging Electrolysis Electrolysis
Electric motor
Mechanical losses
Electric motor
Mechanical losses
Compression/ Transport
Fuel cell
Power-to-Liquid
Transport
Internal combustion engine
Mechanical losses
Fuel cell H2
100 km 40 km 20km
Overall efficiency
%
Overall efficiency
%
Overall efficiency
%
How efficient are the three different technology options?The direct use of electricity – if viable – is 5 times more efficient than synthetic fuels burned in internal combustion engines
The allocation problem – where should PtG and PtL be used in transportSynthetic E-fuels should be used predominantly in areas in which the direct use of electricity is neither technically nor economically viable
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First priority of direct use
of electricity
Supplemental approach for
CO2-based PtG and PtL
Supplemental approach
for Hydrogen H2
Long haul trucks and buses without overhead lines
Inland waterway transport
PtX
Long haul trucks and buses without overhead lines
Trains without overhead lines
Source: based on Agora Verkehrswende (2018).
The future costs of synthetic fuels depend on the costs of power generation (CAPEX+OPEX), and the capacity utilization of conversion facilities
13Source: based on Agora Verkehrswende (2018).
20
15
10
5
02020 2030 2050
Electricity costs
Conversion to hydrogen via electrolysis
Conversion to methane incl. H2 storage
Transport
Diesel
ct/
kW
hm
eth
ane
Generation costs of synthetic methane in North Africa (PV)
Scenario:
CO2 price of 80 €/ton CO2
Conversion costs (electrolyser etc.)
are very sensitive to the load factor.
Full load hours: approx. costs:
2000 h: 20 ct/kWh
8000 h: 5 ct/kWh
and comparison with conventional fuel types(ct/kWhmethane)
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Where Power to X?
The key factor for potential prime PtX locations is the cost of renewable energy
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Wind
PV
Primär PV, teilweise
PV-Wind-Hybrid
PV-Wind-Hybrid
Source: World Energy Council & Frontier Economics (2018).
Chile
Argentina
Bolivia
Peru Brasil
Mexico
USA
Mauritania
Morocco
Spain
AlgeriaLibya
MaliNiger
Chad
South Africa
NamibiaMadagascar
Kenya
Somalia
Sudan
Egypt
Saudi Arabia
Oman
Iran
Afghanistan
Kazakhstan
Russia
Norway
Iceland
Canada
Australia
China
New Zealand
Pakistan
UAE
Qatar
The main part of PtX power currently installed, is located in Germany. Countries such as Morocco and Chile are speeding up
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PtG project allocation differentiated according to the target products
hydrogen and methane as well as activity/inactivity.
Source: Thema, Bauer, & Sterner (2019).
Sustainability assessments must be based on comprehensivesets of economic, social, ecological and governance criteria
SOCIAL i.a.:
• Human Rights, e..g.:
Free, prior, informed consent
• Core labour standards
• Energy poverty
• Access to infrastructure
• Working conditions
• Training
ECONOMIC i.a.
• Decoupled growth
• Local added value
• Job creation
• Export Revenue
ECOLOGIC i.a.:
• Additionality of
renewable energy
• Closed CO2 Cycle
• Water management
• Land use
• Biodiversity
GOVERNANCE i.a.:
• Political stability
• Rule of law
• Transparency
• Institutionalisation
• Property and user
rights
• ConnectivitySustainabilty
Criteria
Reference Docs:
RED II,
UNGP, UN Global Compact, ILO
OECD MNE Guidelines and Due Dilligence Guidance
Sustainability concerns have to be consideredat every step of the PtX global value chain
Power-
generation
location
Transmission
Networks
Electrolyser
Location
Impact / Risks
CO2
capture
Refinery /
Fischer-Trobsch
Synthesis
Type of
Liquid /
Gas
Use options
in transport
Customer
Power to H2
Assessing:
Opportunities
Risks
Impacts
Domestic
Supply / Demand
International
Import / Export
Use options
in industry
H2 storage
transport
infrastructure
H2 to X X = Various Use Options
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Clip explaining Power-to-X can be found online:
https://www.changing-transport.org/video-power-to-x-
how-does-it-work/
Daniel
Bongardt
Heino von
Meyer
Elmar
Schuppe
Charlotte
Hussy
Alexander
Mahler
Noelle
Ziolkowski
The International
PtX Hub
@giztransport
Changing-transport.org
Carl
Kreuzberg