Hitachi Energy – Hitachi Energy selected as consulting partner for world’s first commercial eFuels facility

November 1, 2023
Hitachi Energy

Hitachi Energy and Arcadia eFuels join forces to pioneer the decarbonization of the transport sector and advance the energy transition.

 

Hitachi Energy has been selected by Arcadia eFuels, a leading developer in eFuels, to carry out a grid connection analysis for the world’s first commercial eFuels production facility for sustainable aviation fuels in Vordingborg, Denmark, approximately 100 km south of the Danish capital Copenhagen. 

The planned plant will use 360 megawatts (MW) of renewable electricity, water, and CO2 to produce net zero carbon fuels that can be used in existing engines and infrastructure. The breakthrough eFuels plant will generate around 100 million liters of eFuels per year, allowing airlines to cut down on carbon emissions to meet national and international targets. 

Hitachi Energy will perform a detailed front-end engineering and design (FEED) study for a solution that will enable and optimize the eFuels facility’s grid connection and design. The contract awarded to Hitachi Energy also includes an option to deliver the complete grid connection solutions when the FEED is completed.

Animation of eFuel facility in Vordingborg, Denmark (Source: Arcadia eFuels)

 

“The Arcadia eFuels’ project in Vordingborg is a milestone for both Denmark and globally, and we are very proud to be the partner of choice for this project,” said Claus Madsen, Country Managing Director of Hitachi Energy Denmark.

 

“We are building the first commercial-grade eFuels production plant in an effort to help decarbonize aviation,” said Amy Hebert, CEO of Arcadia eFuels. “Hitachi Energy is a great partner, understanding the crucial need for an energy transition and the expertise to help us achieve the goal of decarbonizing aviation.”

 

“We are happy that Arcadia eFuels has confirmed its confidence in our consulting expertise supporting this vital project to be realized, and together with Arcadia, we are advancing a sustainable energy future for all,” says Daniel Galvan, Head of Power Consulting at Hitachi Energy.

 

The construction of the plant is planned to follow an impressive timeline and is expected to be finished at the end of 2026.

 

 

SourceHitachi Energy

EMR Analysis

More information on Hitachi Energy: See the full profile on EMR Executive Services

More information on Claudio Facchin (Chief Executive Officer, Hitachi Energy): See the full profile on EMR Executive Services

More information on Claus Madsen (Country Managing Director, Hitachi Energy Denmark, Hitachi Energy): See the full profile on EMR Executive Services

More information on Daniel Galvan (Global Head of Service, Grid Integration, Hitachi Energy): See the full profile on EMR Executive Services

 

More information on Arcadia eFuels: https://arcadiaefuels.com/ + eFuels are a credible solution, bringing hope and change to our future. eFuels help our global community through net zero carbon emission travel and transportation of goods. Producing the world’s future fuels to protect our environment and power our world.

More information on Amy Hebert (Chief Executive Officer, Arcadia eFuels): https://arcadiaefuels.com/our-team/ + https://www.linkedin.com/in/amy-hebert-47710b3a/ 

 

 

 

EMR Additional Notes:

  • Biomass:
    • Biomass is renewable organic material that comes from plants and animals. Biomass contains stored chemical energy from the sun that is produced by plants through photosynthesis.
    • Biomass is a clean, renewable energy source. Its initial energy comes from the sun, and plants or algae biomass can regrow in a relatively short amount of time. Trees, crops, and municipal solid waste are consistently available and can be managed sustainably.
  • Bioenergy:
    • It is a form of renewable energy that is derived from recently living organic materials known as biomass, which can be used to produce transportation fuels, heat, electricity, and products.
    • Bioenergy is renewable energy produced from organic matter (called “biomass”) such as plants, which contain energy from sunlight stored as chemical energy. Bioenergy producers can convert this energy into liquid transportation fuel—called “biofuel”—through a chemical conversion process at a biorefinery.
    • Types of bioenergy include biogas, bioethanol, and biodiesel which may be sourced from plants (corn, sugarcane), wood, agricultural wastes, and bagasse. Bioenergy is considered renewable because its source is inexhaustible, as plants obtain their energy from the sun through photosynthesis which can be replenished.
  • Biofuel:
    • Any fuel that is derived from biomass—that is, plant or algae material or animal waste. Since such feedstock material can be replenished readily, biofuel is considered to be a source of renewable energy, unlike fossil fuels such as petroleum, coal, and natural gas.
    • The two most common types of biofuels in use today are ethanol and biodiesel, both of which represent the first generation of biofuel technology.
  • e-Fuels – Electrofuels:
    • eFuels are produced with electricity from renewable sources, water and CO2 and are a sustainable alternative to fossil fuels.
    • Electrofuels, also known as e-fuels or synthetic fuels, are a type of drop-in replacement fuel. They are manufactured using captured carbon dioxide or carbon monoxide, together with hydrogen obtained from sustainable electricity sources such as wind, solar and nuclear power.
  • e-Methanol:
    • eMethanol is also referred to as ‘green’ methanol because of the way in which it is produced: combining biogenic CO2 (put simply, CO2 created by burning biologically based materials, such as biomass) with hydrogen, created by water electrolysis.
    • E-methanol is produced by combining green hydrogen and captured carbon dioxide from industrial sources. It still releases some greenhouse gases as it burns, but it emits less carbon dioxide, nitrogen oxides, sulfur oxide and particulate matter than conventional marine fuel.
    • Methanol – CH3OH – is four parts hydrogen, one part oxygen and one part carbon. On an industrial scale, methanol is predominantly produced from natural gas by reforming the gas with steam and then converting and distilling the resulting synthesized gas mixture to create pure methanol.
  • SAF (Sustainable Aviation Fuel):
    • SAF stands for sustainable aviation fuel. It’s produced from sustainable feedstocks and is very similar in its chemistry to traditional fossil jet fuel. Using SAF results in a reduction in carbon emissions compared to the traditional jet fuel it replaces over the lifecycle of the fuel.
    • SAF is made by blending conventional kerosene (fossil-based) with renewable hydrocarbon. They are certified as “Jet-A1” fuel and can be used without any technical modifications to aircraft.
    • SAF prices are currently about five times higher than prices for conventional jet fuel, data on European spot market prices collected by OPIS show. OPIS is an IHS Markit unit. The disruption to the aviation industry as a result of the COVID-19 pandemic makes cost issues even more prominent today.

 

  • Grid, Microgrids and DERs:
    • The power grid is a network for delivering electricity to consumers. The power grid includes generator stations, transmission lines and towers, and individual consumer distribution lines.
    • The grid constantly balances the supply and demand for the energy that powers everything from industry to household appliances.
    • Electric grids perform three major functions: power generation, transmission, and distribution.
    • A microgrid is a small-scale power grid that can operate independently or collaboratively with other small power grids. The practice of using microgrids is known as distributed, dispersed, decentralized, district or embedded energy production.
    • Smart Grid is any electrical grid + IT at all levels . Micro Grid is a group of interconnected loads and DERs (Distributed energy resources) within a clearly defined electrical and geographical boundaries witch acts as a single controllable entity with respect to the main grid.
    • Distributed energy resources (DERs) are small-scale electricity supply (typically in the range of 3 kW to 50 MW) or demand resources that are interconnected to the electric grid. They are power generation resources and are usually located close to load centers, and can be used individually or in aggregate to provide value to the grid.
    • Common examples of DERs include rooftop solar PV units, natural gas turbines, microturbines, wind turbines, biomass generators, fuel cells, tri-generation units, battery storage, electric vehicles (EV) and EV chargers, and demand response applications.
    • Distributed energy resources management systems (DERMS) are platforms which helps mostly distribution system operators (DSO) manage their grids that are mainly based on distributed energy resources (DER).
    • DERMS are used by utilities and other energy companies to aggregate a large energy load for participation in the demand response market. DERMS can be defined in many ways, depending on the use case and underlying energy asset.

 

  • Kilowatt (kW):
    • A kilowatt is simply a measure of how much power an electric appliance consumes—it’s 1,000 watts to be exact. You can quickly convert watts (W) to kilowatts (kW) by diving your wattage by 1,000: 1,000W 1,000 = 1 kW.
  • Megawatt (MW):
    • One megawatt equals one million watts or 1,000 kilowatts, roughly enough electricity for the instantaneous demand of 750 homes at once.
  • Gigawatt (GW):
    • A gigawatt (GW) is a unit of power, and it is equal to one billion watts.
    • According to the Department of Energy, generating one GW of power takes over three million solar panels or 310 utility-scale wind turbines

 

  • Carbon Dioxide (CO2):
    • Primary greenhouse gas emitted through human activities. Carbon dioxide enters the atmosphere through burning fossil fuels (coal, natural gas, and oil), solid waste, trees and other biological materials, and also as a result of certain chemical reactions (e.g., manufacture of cement). Carbon dioxide is removed from the atmosphere (or “sequestered”) when it is absorbed by plants as part of the biological carbon cycle.
  • Biogenic Carbon Dioxide (CO2):
    • Carbon Dioxide released as a result of the combustion or decomposition of organic material, that is biomass and its derivatives. Examples include carbon dioxide released during the combustion of wood and biogas generated by decomposition.
    • Biogenic Carbon Dioxide (CO2) and Carbon Dioxide (CO2) are the same. Scientists differentiate between biogenic carbon (that which is absorbed, stored and emitted by organic matter like soil, trees, plants and grasses) and non-biogenic carbon (that found in all other sources, most notably in fossil fuels like oil, coal and gas).
  • Carbon Capture and Storage (CCS):
    • CCS involves the capture of carbon dioxide (CO2) emissions from industrial processes, such as steel and cement production, or from the burning of fossil fuels in power generation. This carbon is then transported from where it was produced, via ship or in a pipeline, and stored deep underground in geological formations.
    • CCS projects typically target 90 percent efficiency, meaning that 90 percent of the carbon dioxide from the power plant will be captured and stored.
  • Decarbonization:
    • Reduction of carbon dioxide emissions through the use of low carbon power sources, achieving a lower output of greenhouse gasses into the atmosphere.