15Apr

Learn about the innovative techniques for reducing carbon dioxide emissions in biogas production.

Introduction: Biogas, a renewable energy source produced from organic materials like agricultural waste, food waste, and sewage, offers a promising avenue for reducing greenhouse gas emissions and mitigating climate change. However, biogas typically contains anywhere from 25 to 55% of carbon dioxide which means using biogas as a fuel source to generate heat or electricity will exhaust this quantity of carbon dioxide plus any additional carbon dioxide that is created by the combustion process straight into the atmosphere. To address this issue, innovative techniques such as post and pre-combustion scrubbing of carbon dioxide have emerged as effective means of capturing carbon dioxide emissions from biogas. In this article, we delve into the workings of post and pre-combustion scrubbing, their benefits, and why they are necessary to reduce carbon emissions.

Post-Combustion Scrubbing: Post-combustion scrubbing involves capturing carbon dioxide after the combustion process. This method is highly adaptable and can be retrofitted onto existing biogas combustion systems. The primary mechanism involves passing the flue gas generated from combustion through an absorption medium, typically a solvent like amines, or a membrane that selectively captures carbon dioxide molecules. Once captured, the carbon dioxide can be separated from the solvent or membrane and stored or repurposed for various industrial processes. One significant advantage of post-combustion scrubbing is its flexibility. It can be integrated into a wide range of biogas combustion systems, from small-scale digesters to large industrial facilities, without significant modifications to the existing infrastructure. Additionally, post-combustion scrubbing allows for the continuous operation of biogas facilities while reducing carbon dioxide emissions, making it a practical solution for sustainable energy production.

Pre-Combustion Scrubbing: Pre-combustion scrubbing, on the other hand, involves capturing carbon dioxide before the combustion process occurs. This method is commonly employed in conjunction with biogas upgrading processes such as biogas purification and biogas-to-methane conversion. During pre-combustion scrubbing, carbon dioxide is removed from the raw biogas stream, resulting in a purified methane-rich gas that can be utilised directly as a cleaner fuel or further processed into biomethane for injection into the natural gas grid. Pre-combustion scrubbing offers several advantages, particularly in enhancing the calorific value and purity of biogas-derived fuels. By removing carbon dioxide before combustion, the efficiency of biogas utilisation increases, resulting in higher energy yields and reduced emissions. Moreover, the captured carbon dioxide can be sequestered or utilised in industrial processes, further enhancing the environmental sustainability of biogas production.

Applications and Future Prospects: MTTST has developed both post and pre-combustion scrubbing technologies that can be used by biogas production facilities to lower their overall carbon footprint. From small-scale anaerobic digesters to large-scale biogas plants, these techniques can help reduce the carbon footprint of biogas-derived energy and contribute to global efforts to combat climate change.

Conclusion: Post and pre-combustion scrubbing is essential to sustainable energy production from biogas. Capturing carbon dioxide and reducing emissions from biogas combustion processes, results in a cleaner, more environmentally friendly fuel while mitigating the impact of greenhouse gas emissions on the climate. As the demand for renewable energy continues to grow, it is essential to implement post and pre-combustion scrubbing technologies, paving the way for a more sustainable energy future.

28Feb

What are the challenges that prevent industries from incorporating new technologies effectively?

Many industries still rely on separation technology that is two to three decades old. While this technology is reliable and technically sound, it is akin to driving a car that is two to three decades old. At first glance, the basic principles may seem similar, but a closer examination reveals significant differences. Comparing an old car to a new one, you will notice the latter's additional safety features, compact design, fuel efficiency, and lower emissions not to mention other benefits. Likewise, advanced separation technologies share similar traits: they occupy less space, resulting in a smaller carbon footprint; they demand less energy, enhancing efficiency; and they offer superior separation performance, which benefits the environment. Most people don't regularly use vehicles that are more than two to three decades old unless they are classic cars reserved for special occasions or weekend drives. So, why does the industry lag in adopting these advancements?

23Feb

Improve existing produced water treatment systems with patented next generation technology that minimises oil concentration in produced water. This in turn helps reducing the environmental impact of oil producing platforms.

https://www.offshore-mag.com/print/content/14172708

In many industries, there's often talk about minimising environmental impact, yet action often falls short. It's clear that outdated Hydrocyclone technology no longer meets the stringent demands of minimising environmental risks, especially under ISO 31000 guidelines. This is particularly evident when dealing with contaminants beyond just oil in water in discharged formation water.

Introducing the Stauper CFU technology represents a significant leap forward. Not only does it achieve oil-in-water discharge levels below 10ppm, but it also effectively removes other contaminants, including solids. This innovative third-generation CFU is patented and offers a comprehensive solution to mitigate environmental risks associated with formation water discharge. 

Let's take proactive steps to truly address environmental impact. By adopting the advanced Stauper CFU technology, we can effectively reduce formation water discharge risks to the lowest practical levels possible. It's time to act responsibly and implement solutions that align with our commitment to environmental stewardship.