Bio Energy with Carbon Capture and Storage PDF

Summary

This presentation discusses bioenergy with carbon capture and storage (BECCS), focusing on the Drax Power Station and related topics. It explores different methods for capturing carbon dioxide emissions, such as using forests, peatlands, and soil.

Full Transcript

Bio Energy with Carbon Capture
and Storage (BECCS)
ENE1001 Renewable Energy Systems 1
Prof Justin Hinshelwood
Overview
Drax Power Station
History
Biomass
CCS
UK Government plans
Alternative plans
Drax Power Station
 Drax History
Construction and Early Years (1967-1986):
largest coal-fired power station in the UK,
4,000 megawatts (MW)
Peak Operation as a Coal Plant (1980s-2000s):
ten million tonnes of coal per year
iconic cooling towers and massive coal stacks
symbolizing the industrial might of Britain’s power generation
Environmental Upgrades (2000s):
flue-gas desulfurization units to reduce sulfur dioxide emissions
Transition to Biomass (2012-2020):
four out of six units switched to burning sustainable wood pellets,
largest renewable energy plant in the UK.
Carbon Capture and Storage Plans (2020-Present):
planning to implement Bioenergy with Carbon Capture and Storage (BECCS) technology,
2024
Largest single renewable energy generator
5% of UK electricity generation
~£150 per MWh
 Drax Biomass Enterprise

Tree growing nursery
Working forests Saw mill and pellet plant

Ports and logistics
Drax
Drax History
https://www.drax.com/resources/educational-resources/
CCS Potential
BECCS
Potential to remove 20-70 million tonnes of CO2 per year in the UK by 2050
National Grid’s Net Zero Future Energy Scenarios (FES)
Propose the use of BECCS by 2028
UK Climate Change Committee
BECCS will be needed to meet 2050 targets
70 billion tonnes of potential CO2 storage space around the UK
British Geological Survey
Drax could develop two BECCS units by 2030
Potential to deliver 40% of the negative emissions for the UK to reach net zero.
Greenhouse Gas Removal Methods …
UK Committee on Climate Change
 Forests and better forest management
Potential advantages Potential disadvantages
Costs are relatively low It takes time for trees
Potential to store to mature (at least 10
carbon is well known years)
and understood Uses land that could
Could store significant be used for other
amount of carbon activities
dioxide Could have a negative
impact on biodiversity

Infographic from the Royal Society and Royal Academy of Engineering (2018)

2
 Peatlands and wetlands
Potential
Potential advantages
disadvantages
We know how to Understand less about
restore peatlands and the science of storing
wetlands carbon in these places
A quick way to store for a long time
carbon at relatively low Uses land that could
cost be used for something
Could have other else
economic Limited potential: only
environmental some areas of the UK
benefits are suitable

Infographic from the Royal Society and Royal Academy of Engineering (2018)

4
 Enhancing the storage of carbon in soil
Potential advantages Potential disadvantages
Well-understood method that can be Requires changes to modern farming
implemented now practices
Could have a low cost Farmers may need financial support from
Could have other economic and government
environmental benefits Could reduce amount of food that can be
produced from a given area of land

Infographic from the Royal Society and Royal Academy of Engineering (2018)

6
 Using wood in construction
Potential advantages Potential disadvantages
Wood has been used in Requires changes to modern
construction for centuries building practices
A relatively low cost way to store May mean very tall buildings are not
carbon possible
Reduces carbon emissions by Scale might be limited by
replacing other carbon-intensive availability of sustainable sources
materials of wood

Infographic from the Royal Society and Royal Academy of Engineering (2018)

8
 Bioenergy with carbon capture and storage (BECCS)
Potential advantages Potential disadvantages

Could capture and store a significant amount of carbon dioxide emissions Likely to have high costs, at least initially
Combines technologies that are well understood Uses land that could be used for other activities
Lots of storage space in the UK (e.g. oil and gas fields) Need to ensure that carbon dioxide storage is secure

10 Infographic adapted from the Royal Society and Royal Academy of Engineering (2018)
 Direct air capture and carbon storage
Potential advantages Potential disadvantages
Could capture and store a significant Technologies are very new and
amount of carbon dioxide emissions experimental
Lots of storage space in the UK (e.g. oil Could require a large amount of low
and gas fields) carbon electricity
A variety of technical options are being Current costs are very high, though
developed they could fall as technology improves

15 Infographic adapted from the Royal Society and Royal Academy of Engineering (2018)
Bioenergy with Carbon Capture and Storage
(BECCS)
Combines bioenergy generation with carbon capture to remove CO₂
Developing technology
Several pilot projects running worldwide.
Drax plans to build the world's largest BECCS
Aiming to capture 8 MT of CO₂ annually by 2030
Negative emissions
Capturing more CO₂ than is emitted during energy production
Issues
Policy and Funding Challenges
Technological Risks
Investment and Market Support
Energy Intensive Process
Infrastructure Needs
Public Perception and Acceptance
CCS
Before fuel is burnt: Pre-combustion
After fuel is burnt: Post combustion
Oxyfuel combustion
Cost
32% gas plants
65% coal fired plants
Precombustion Syngas (H2 +CO)
Post combustion
Before traveling up
smokestacks
Waste gasses captured
Scrubbed clean of CO2
Passing the gasses through
ammonia
Blasted with stem to release
CO2
Oxyfuel
Incomplete
Power plants do not produce pure CO2
Incomplete combustion (not enough O2)
Other gasses produced
Oxyfuel process
Combustion enriched with higher levels of O2
Purer steam and CO2 produced
Steam removed (condense steam)
CO2 stored
Transportation
Move CO2 to storage site
Pipeline?
Ship?
Storage: Geo Sequestration
Pros and Cons
Advantages
Reduce plant emissions by more than 80%
NOxs and SOxs also removed
Disadvantages
Unproven technology
Increase emissions of acid gas pollutants
Increase fuel needs of power plants by 25-40%
Cost of energy increased by 21-91%
High water use
 UK Government investment:
£22B over 25 years

Category Estimated Allocation (£)
Industrial Clusters and Pipelines £6-8 billion
Power Generation and Operational Subsidies £5-7 billion
Direct Air Capture (DAC) £2-3 billion
Innovation and Technology Development £2-4 billion
Private Sector Support and Co-Investment £3-5 billion
Monitoring and Long-Term Maintenance £1 billion
International Collaboration £0.5-1 billion
CCS Credentials
Track record of overpromising and underdelivering
Current CCS capacity: 80% of the CO₂ captured is reinjected into oil fields to
facilitate oil extraction
Only 2 commercial-scale coal plants operate with CCS:
Boundary Dam in Canada and Petra Nova in the US recurring technical issues and ballooning costs
Britain has closed down its last coal power plant
Harder to capture CO₂ from gas power plants than from coal
Blue hydrogen projects (gas->H2) abandoned
 Alternative Allocation

Category Estimated Allocation (£)
Renewable Energy Expansion £8-10 billion
Hydrogen Production and Infrastructure £5-7 billion
Industry Electrification and Efficiency £3-4 billion
Natural Climate Solutions £3 billion
Building Decarbonization £2-3 billion
R&D in Low-Carbon Technology £2-3 billion
Sustainable Transport and Urban Design £2 billion
Education and Behavioral Change £0.5-1 billion
 Alternative Allocation
Accelerate Renewable Energy Expansion £8-10 billion Energy Efficiency and Decarbonization in Buildings £2-3 billion
Solar and offshore wind: most cost-effective and scalable generation Retrofit Program for Residential and Commercial Buildings
Battery storage technology: reduce the need for gas generation Building Standards and Low-Carbon Materials
Modernise the grid to support decentralized generation

Research and Development in Emissions-Free Technologies £2-3 billion
Boost Hydrogen Production and Infrastructure £5-7 billion
Innovation in Low-Carbon Technologies
Green Hydrogen Production: fuel for heavy industry, transport, heating
Circular Economy and Recycling Technologies

Electrification and Energy Efficiency in Industry £3-4 billion
Clean Public Transport and Sustainable Urban Design £2 billion
Electrification in industrial processes
Public Transport Electrification
Industrial Heat Pump Systems
Energy Efficiency Upgrades manufacturing, Cycling and Pedestrian Infrastructure
Electric Vehicle (EV) Infrastructure

Carbon Sequestration through Natural Climate Solutions £3 billion
Reforestation and Afforestation Behavioural Change and Education Programs £0.5-1 billion
Peatland and Wetland Restoration Public Awareness Campaigns
Soil Carbon Sequestration Incentives for Sustainable Lifestyles
Review
Drax Power Station
History
Biomass
CCS
UK Government plans
Alternative plans