2nd E-Newsletter / January 2025

Source: Valio

• CANMILK WELCOMES NEW PROJECT PARTNER
• SPOTLIGHT TOPIC: PROOF-OF-CONCEPT UNIT
• ACTIVITIES OF THE PAST MONTHS

Welcome to the second edition of the CANMILK E-Newsletter - here you'll find everything from the latest project updates to exciting team highlights!

In this issue you can read about the development of the Proof of Concept unit, meet our new project partner and read about other project updates.

Want to learn more? Then explore CANMILK online. Visit our website for in-depth information on our project, team, and activities or follow us on social media for real-time updates and behind-the-scenes glimpses of our ongoing work:

Thank you for your ongoing support and enthusiasm for the CANMILK project. We hope you enjoy reading this issue.

Warm regards,

The CANMILK Project Team

The CANMILK project welcomed a new project partner in October 2024: The Instituto Superior Técnico (IST), the school of Engineering and Technology of the University of Lisbon. IST joins with two research centres, the Institute for Plasmas and Nuclear Fusion (IPFN) and the Centre of Structural Chemistry (CQE), and will play a crucial role in plasma modelling and diagnostics, a key component in CANMILK’s efforts to mitigate methane emissions from cattle barns.

IST will enhance the project’s technical capabilities by developing and validating advanced models for methane and plasma interactions with catalytic surfaces. Their expertise in methane oxidation and surface kinetics will be vital in understanding the key reactions that drive methane conversion.

Learn more: https://canmilk.eu/2024/10/28/canmilk-welcomes-new-consortium-partner/

The CANMILK project is dedicated to developing innovative technologies for reducing methane emissions in dairy barns. A key component of the project is the development of a proof-of-concept (PoC) unit that will lay the foundation for subsequent prototype development. The focus is on using plasma technology to activate and break down methane. In an interview with Jasmiina Palo, project manager at VTT, she outlines the main steps and objectives of the development phase of the PoC unit.

The VTT team is working on the design of the plasma unit and the gas feeding system.

What is the purpose of developing a proof-of-concept (PoC) unit in the CANMILK project?

In the CANMILK project, we have set an ambitious goal: to convert 90% of methane into less harmful carbon dioxide (CO2) by utilizing integrated adsorption and plasma technologies. To achieve this, we are constructing a POC system that will enable us to test our proposed concept. It’s important to distinguish between the demonstration unit and the PoC unit. The scale of the PoC unit can range from milliliters to liters, and the goal is to test innovative concepts that have not been explored before.

What are the key components of the PoC unit?

In the CANMILK process, the primary components are the plasma reactor and the adsorber unit. The adsorber unit first concentrates ultra-dilute methane from barn air, and then the plasma unit converts it into less harmful compounds. Our initial plan involves using non-thermal plasma in conjunction with a concentrated stream from the adsorber unit to achieve a targeted methane removal rate of 90%.

With the PoC system, we can also investigate other types of plasma, such as microwave plasma, to evaluate various parameters beyond methane conversion, including energy efficiency, which may be more applicable for larger-scale implementations.

Can you describe the process of designing the PoC unit? What were the key challenges?

The design of the PoC unit can be characterized as a small-scale project. It is crucial to establish clear objectives that outline the goals of the PoC, including the identification of essential features, functionalities, and performance metrics. Additionally, when the design involves collaboration—such as in the CANMILK project—smooth communication among all stakeholders is vital throughout every phase of the project. This includes the design and development, implementation, testing, and validation stages. In fact, communication challenges can become a significant bottleneck in the design process, alongside technical uncertainties arising from the very low technology readiness levels found in projects like CANMILK.

What kind of data was needed for the design of the PoC?

Technical design starts with defining the boundary conditions, which entails understanding the operating environment. In the project's first year, we conducted comprehensive air measurements in a real barn in Arvela, Finland. During these measurements, we monitored methane and other impurities, including ammonia, sulfur compounds, and carbon dioxide. This helped us gain a better understanding of the operational environment and the requirements for the PoC unit. As a result, we were able to establish several technical boundaries for the PoC unit, including its scale and operating conditions, based on the data gathered from the barn air measurements.

A photo from VTT Bioruukki showing the construction of a gas-feeding system.

Once the PoC unit is constructed, what testing procedures will it undergo, and what are the key metrics for success?

Once the reactor and adsorber units are constructed, they will be tested individually before being integrated into a single test train at VTT's facilities. The proof-of-concept tests will use simulated gas mixtures to establish stable operation for a duration of 20 to 100 hours, with the goal of achieving 90% methane conversion. Furthermore, we have the capability to test various gas compositions and operational modes to optimize the system.

How do you simulate real-world barn conditions during the testing phase?

In the first year of the project, we collected data from the barn air measurement campaign, which will serve as our foundation. Using the PoC unit, we can replicate the conditions of the barn air by creating a gas mixture that includes pure, bottled gases and water to simulate the humidity present in the barn air.

How will the PoC unit be integrated into a real barn environment, and what challenges do you anticipate during this process?

As a follow-up project, testing the PoC unit under real barn conditions could be considered. This, of course, depends on the outcome of the tests at VTT Bioruukki.

Highlighting Project Research 

The CANMILK consortium aims to bring its research closer to its stakeholders by publishing articles on current research topics on its project website. Read more about VTT's research on methane oxidation in DBD reactors - the role of catalysts and about the diverse potential of plasma in sustainable chemistry.

CANMILK Project Video 

The CANMILK project video is available online, offering an insightful overview of the project’s background, objectives, and innovative approach. It highlights the urgency of tackling agricultural methane emissions and presents CANMILK’s solution using non-thermal plasma technology to convert methane into less harmful CO2. Viewers can gain a deeper understanding of how CANMILK contributes to the global effort of achieving carbon neutrality.

Investigation of Methane in Cattle Barn Housing

Durham University presented research from the CANMILK project at the IFEAA Deep Dive event in Bristol in November 2024. The presentation included experimental results and computational modelling efforts to address methane emissions in dairy barn housing. The work is investigating the key factors affecting methane concentrations in housed cattle, particularly focusing on methane production, ventilation, and environmental conditions, with the intention of understanding how a direct air capture system could be implemented within the barn. 

Poster Presentation on Noble Metal Catalysts for plasma-assissted oxidation of Methane

PhD student Abhinash Kumar Singh represented the CANMILK project at the 20th Nordic Symposium on Catalysis (NSC) in Stavanger, Norway, and the ISCRE 28 International Symposium on Chemical Reaction Engineering 2024 in Turku, Finland. Singh’s poster presentation highlighted the latest advances in non-thermal plasma-assisted catalytic oxidation of methane, with a focus on the effects of different catalysts. This research is important for achieving the methane abatement goals of the CANMILK project. Singh’s work aims to improve the efficiency and selectivity of methane oxidation processes. 

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