Centrica Energy, Bord Gáis Energy And Mitsubishi Power Announce Development Of Europe’s First Ammonia Fired Power Generation Facility
The title of this post, is the same as that of this press release from Centrica.
This is the sub-heading.
Centrica plc and Mitsubishi Power Europe Limited “Mitsubishi Power Europe” have signed a Memorandum of Understanding (MOU) to explore the development, construction, and operation of Europe’s first-ever ammonia-fired power generation facility at Bord Gáis Energy’s Whitegate Combined Cycle Gas Turbine (CCGT) power station in Cork, Ireland.
These four paragraphs outline the project.
The project is being led by Centrica through its Bord Gáis Energy and Centrica Energy businesses and Mitsubishi Power Europe and would become Europe’s inaugural ammonia-fired power generation facility and one of only two such facilities in the world.
The utilisation of low carbon ammonia as a clean and sustainable fuel source for power generation has the potential to provide security of supply while reducing greenhouse gas emissions. Low carbon ammonia has a higher volumetric density than hydrogen, enabling the utilisation of low carbon hydrogen in a form which is easy to transport and store, resulting in a fuel that can be combusted with no carbon emissions at point of use. Its use as a fuel is a promising long-term energy solution for the transition to a low-carbon energy value chain.
Bord Gáis Energy’s facility at Whitegate CCGT power station would serve as a global demonstration site for ammonia-fired power generation technology, providing insight into the feasibility and scalability of low carbon ammonia as a green fuel and shaping the future of power generation worldwide, with low carbon ammonia being sourced through Centrica Energy’s global trading network.
Following the signing of the MOU, the project team is being established to commence project feasibility assessments. Upon the successful outcome of this assessment, extensive local stakeholder engagement will commence.
Note.
- No mention of the size of the new power station is given in the press release.
- Whitegate power station is a 445 MW combined cycle gas turbine (CCGT), that was built in 2010.
- It can meet ten percent of Ireland’s electricity demand.
I have a few thoughts.
Will The Existing Power Station Be Converted To Ammonia Or Will A New Ammonia-Fired Power Station Be Built Alongside?
Consider.
- If the second station doesn’t work, there’s no reduction in power.
- If a replacement station doesn’t work, ten percent of Ireland will be in the dark.
- Ireland will be needing more power in the next few years.
- A second power station can be appropriately-sized.
- Japanese don’t like to lose face!
Prudence probably says that building a second station alongside is the least risky route.
Wind Power In Ireland
This Wikipedia entry is entitled Wind Power In Ireland.
This is the first paragraph.
As of 2021 the island of Ireland has 5,585 megawatt and the Republic of Ireland has 4,309 MW of installed wind power nameplate capacity, the third highest per capita in the world. In 2020 wind turbines generated 36.3% of Ireland’s electrical demand, one of the highest wind power penetrations in the world.
There is also one 500 MW interconnector between the islands of Great Britain and Ireland, with another similar-sized one under construction.
As the wind doesn’t blow all the time, the island of Ireland will need some low-carbon backup.
Why Ammonia?
This paragraph from the press release gives several reasons.
The utilisation of low carbon ammonia as a clean and sustainable fuel source for power generation has the potential to provide security of supply while reducing greenhouse gas emissions. Low carbon ammonia has a higher volumetric density than hydrogen, enabling the utilisation of low carbon hydrogen in a form which is easy to transport and store, resulting in a fuel that can be combusted with no carbon emissions at point of use. Its use as a fuel is a promising long-term energy solution for the transition to a low-carbon energy value chain.
There may also be secondary issues here.
If you read the Applications section in the Wikipedia entry for ammonia, you will realise, what a useful chemical ammonia is.
As Ireland has a lot of agriculture, a fertiliser plant could be located close to the power station.
If the ammonia was green ammonia, then this will help to decarbonise the island of Ireland.
Where Will The Green Ammonia Come From?
These posts deal with the production and distribution of green ammonia.
- Could West Africa Become A Green Energy Powerhouse?
- H2U Eyre Peninsula Gateway Hydrogen Project Begins Largest Green Ammonia Plant
- KEPSA Signs Large-Scale Green Energy Projects MoU In Kenya
- Namibia Is Building A Reputation For The Cheapest Green Hydrogen
- Uniper To Make Wilhelmshaven German Hub For Green Hydrogen; Green Ammonia Import Terminal
Note.
- A continent with a lot of renewable energy like Africa or Australia can create lots of green ammonia.
- As the press release says, ammonia is easier to transport and store compared to hydrogen.
- The press release says that low carbon ammonia will be sourced through Centrica Energy’s global trading network.
- Fortescue Future Industries is mentioned in several posts, as producers of green hydrogen and green ammonia.
- Centrica is big enough to stand up to Andrew “Twiggy” Forrest and Fortescue Future Industries.
As in a few years, we will have many GWs of renewable energy, could we be making green ammonia for the Irish?
This news story on the UK Research and Innovation web site is entitled Designs For Green Ammonia Plant Become Reality.
This is the sub-heading.
Science and Technology Facilities Council (STFC) researchers are building a small-scale plant to generate ammonia using only renewable energy sources.
These two paragraphs outline the story.
Ammonia is a promising carbon-free fuel source of the future and so if successful, the plant has the potential to considerably advance the UK’s net zero ambitions.
It marks the second phase of the Ammonia Synthesis Plant from Intermittent Renewable Energy (ASPIRE) initiative which will be led by STFC in conjunction with the University of Bath, Johnson Matthey, and Frazer-Nash Consultancy.
The UK Research and Innovation news story has this description of the ASPIRE technology.
Current commercial ammonia synthesis is optimised for near steady production requiring constant power.
The first phase of ASPIRE however saw the design of a patented modular reactor and thermal management system that should enable operation from an intermittent renewable power supply.
The new plant will have three core elements:
- a pressure swing adsorption system which extracts nitrogen from air
- a modular electrolyser which splits hydrogen from water
- a synthesis loop that uses the modular reactor and a thermal management system to combine hydrogen and nitrogen to make ammonia
This will enable the entire production process to operate autonomously, powered by a small wind turbine and series of solar canopies with an ammonia generation rate proportional to the available renewable power.
There is even this quote from a Dr. Alan Partridge.
Thanks to the incredible work on this initiative by the team at Rutherford Appleton Laboratory as well as the University of Bath and private sector partners, we are closer than ever to producing industry-scale green ammonia for the UK and the world.
Perhaps, this technology will allow the island of Ireland to make all the green ammonia it needs.
Will Centrica Be Going Into The Green Ammonia Business?
The Centrica press release says they will be dealing in green ammonia for the benefit of Ireland. So Yes!
Conclusion
The news story on the UK Research and Innovation web site is a must-read.
As we have so much renewable energy in the UK, some company will build an ASPIRE-based green ammonia plant in the UK.
Merthyr Tydfil Station – 28th November 2023
Yesterday, I went to South Wales to look at the progress of the South Wales Metro.
I took these pictures at the station and in the town.
Note.
- It is only a single-platform station.
- The platform and track appear to be reasonably flat.
- Several bay terminal platforms in the UK like four of those at Dalston Junction and Highbury & Islington stations near me are able to handle four trains per hour (tph).
- The Class 150/2 trains in the are 19.74 metres long and have a maximum capacity of 149.
- The new electric Class 398 tram-trains are 40.07 metres long and have a capacity of 252.
The platform appears to be long enough for the new trains.
These are my thoughts.
Capacity To And From Merthyr Tydfil
Consider.
- Currently, there are two Class 150/2 tph.
- This means current capacity is 298 passengers per hour.
- After electrification, there will be four Class 398 tph.
- This means future capacity is 1008 passengers per hour.
That is an increase of 238 % in the capacity.
Where Is The Electrification?
This OpenRailwayMap shows the proposed electrification at Merthyr Tydfil station.
Note.
- Electrified lines are shown in red.
- Unelectrified lines are shown in black.
- The railway is single-track until past Troed-y-Rhiw, after which it is double track to Merthyr Vale station.
- Between Merthyr Vale and Abercynon is single-track, with a short length of unelectrified double-track at Quaker’s Yard station.
It appears that the section of the Merthyr Line at Merthyr Tydfil station will not be electrified.
- The tram-trains’ batteries must be large enough to climb the unelectrified section .
- There must also be enough power to nudge the tram-train back down the hill, after the climb has been completed.
- At least the pictures show, that the track in Merthyr Tydfil station, is reasonably flat.
It looks to be a neat piece of cost-saving design.
Why Did I Feel Better In Merthyr Tydfil?
I have been feeling under the weather lately, but I felt a lot better in Merthyr!
Was it the altitude of 180 metres?
My cardiologist friend, says most people feel worse at altitude. But I seem to be the other way round.
My wife was certainly feeling rough, when I drove a car up to 13,000 feet in the Andes of Ecuador, whereas I was fine.
Incidentally, the car was coughing and wheezing like a good ‘un.
Malaysian Fabrication Company Enters Offshore Wind Market With IJmuiden Ver Alpha Contract
The title of this post, is the same as that of this article on offshoreWIND.biz.
This is the sub-heading.
Malaysia Marine and Heavy Engineering Holdings Berhad (MHB), through its wholly-owned subsidiary Malaysia Marine and Heavy Engineering (MMHE), has secured a subcontract for its first offshore substation high-voltage direct current (HVDC) platform required for TenneT’s 2 GW offshore wind project in the Netherlands
These two paragraphs outline the project.
The Malaysian contractor confirmed the award from Petrofac on 29 November and said the OSS HVDC platform consists of a topside and jacket for the IJmuiden Ver Alpha project.
The subcontract scope consists of construction engineering, fabrication, mechanical completion, load out and sea fastening, and architectual works on engineering, procurement, and construction (EPC) basis.
A third paragraph, indicates, that this contract could be the first of a few.
In addition, the parties will also collaborate towards the possibility of fabrication works for two additional offshore substation units of similar size.
This story illustrates how wind farm developers are looking for more places to build their infrastructure.
In An Elegant Solution, I talked about an idea called a D-Floater. Five are shown being transported in this picture.
The idea is from a Swedish company; Bassoe Technology.
This would enable transport costs from faraway places to be reduced.
Nearer to Europe, the Black Sea ports of the Ukraine could be an ideal place to build infrastructure, as the country used to have the required skills, ports and steel-making capabilities.
But first Putin must be put back in his box!
UK Offshore Wind And CCS Colocation Projects Kick Off
The title of this post, is the same as that of this article on offshoreWIND.biz.
This is the sub-heading.
The Offshore Wind and Carbon Capture and Storage (CCS) Colocation Forum (the Forum), set up to provide strategic coordination of colocation research and activity on the nation’s seabed, has commissioned two research projects.
These first two paragraphs, which set objectives and possible methods for the two projects.
The projects are designed to inform the best approach to test and demonstrate the colocation of offshore wind and CCS activities in the future.
The research projects – Project Colocate and Project Anemone – build on the Forum’s Spatial Characterisation Report, which identified areas of potential overlap for offshore wind and CCS on the seabed, and NSTA’s Seismic Imaging Report, which explored various options for monitoring carbon storage and offshore wind sites to help resolve possible colocation issues.
These are the two projects.
Project Colocate, which is described in the article like this.
Delivered by the University of Aberdeen with funding from the Crown Estate and Crown Estate Scotland, Project Colocate will investigate the viability of areas on the seabed for colocation of CCS and offshore wind, with bespoke monitoring plans for each area.
Researchers from the University of Aberdeen will focus their investigations on the East Irish Sea and Central North Sea, both of which have been identified as having significant potential for future colocation of CCS and offshore wind, according to the Crown Estate.
Project Anenome, which is described in the article like this.
The complementary Project Anemone will explore mutually beneficial opportunities arising from the colocation of these developing industries.
The project aims to identify and map the routes to realising these opportunities to create practical guidance for how offshore wind and CCS technologies can operate alongside each other – from construction to decommissioning.
It does appear to be a lot of sensible thinking and words, although neither project appears to yet have a website.
This paragraph is a nice tailpiece to the article.
To achieve the UK’s net zero targets, the UK Government is targeting the delivery of 50 GW of offshore wind energy and the capture of 20-30 million tonnes of CO2 per year by 2030.
I’ve mentioned 50 GW of offshore wind before, but 20-30 million tonnes is a lot of CO2.
The Anonymous Widower 