Biogas Upgrading and Utilization

Detailed overview of innovation with sample startups and prominent university research


What it is

Biogas upgrading and utilization involve processing raw biogas, a mixture of methane (CH4) and carbon dioxide (CO2) produced from anaerobic digestion, to increase its methane content and make it suitable for various applications, such as pipeline injection, vehicle fuel, or electricity generation. This process enhances the value and versatility of biogas, contributing to renewable energy production and reducing greenhouse gas emissions.

Impact on climate action

Biogas Upgrading and Utilization in Agro-Waste Management advances climate action by converting agricultural waste into renewable energy. By upgrading biogas to biomethane and utilizing it as a clean fuel, this innovation reduces methane emissions, displaces fossil fuels, and contributes to a more sustainable and low-carbon energy system.

Underlying
Technology

  • Biogas Composition: Raw biogas typically contains 50-70% methane, with the remainder being primarily carbon dioxide and trace amounts of other gases. Upgrading aims to increase the methane content to over 90%, making it comparable to natural gas.
  • Upgrading Technologies: Several technologies are used for biogas upgrading, including:
    • Membrane Separation: This technology utilizes membranes with selective permeability to separate methane from carbon dioxide and other impurities.
    • Pressure Swing Adsorption (PSA): PSA systems use adsorbent materials to selectively adsorb carbon dioxide and other impurities from biogas, leaving behind a methane-rich gas stream.
    • Water Scrubbing: This method uses water to absorb carbon dioxide from biogas, leaving behind a methane-rich gas stream.
    • Chemical Absorption: Chemical solvents can be used to selectively absorb carbon dioxide and other impurities from biogas.
  • Utilization Pathways: Upgraded biogas, or biomethane, can be used for various applications, including:
    • Pipeline Injection: Biomethane can be injected into natural gas pipelines, displacing fossil fuels and providing a renewable source of energy for heating, cooking, and electricity generation.
    • Vehicle Fuel: Biomethane can be used as a transportation fuel for natural gas vehicles (NGVs), offering a lower-carbon alternative to gasoline and diesel.
    • Electricity Generation: Biomethane can be used to fuel gas engines or turbines to generate electricity.

TRL : 7-8


Prominent Innovation themes

  • Advanced Membrane Materials: Researchers are developing new membrane materials with improved selectivity and permeability, enhancing the efficiency and cost-effectiveness of membrane separation for biogas upgrading.
  • Hybrid Upgrading Systems: Hybrid systems that combine different upgrading technologies, such as membrane separation and PSA, can offer advantages in terms of efficiency and flexibility.
  • Biogas Purification Technologies: Innovations in biogas purification technologies are removing trace contaminants, such as hydrogen sulfide and siloxanes, from biogas, improving its quality and suitability for various applications.
  • Small-Scale Biogas Upgrading Systems: Smaller-scale biogas upgrading systems are being developed for on-farm or distributed biogas production, making biomethane more accessible for local use.

Other Innovation Subthemes

  • Membrane Separation Technology Advancements
  • Hybrid Upgrading Systems Integration
  • Enhanced Biogas Purification Techniques
  • Miniaturized Biogas Upgrading Solutions
  • Biogas Utilization in Natural Gas Pipelines
  • Biomethane as a Sustainable Vehicle Fuel
  • Power Generation from Upgraded Biogas
  • Advanced Membrane Materials Research
  • Efficiency Boost in Pressure Swing Adsorption
  • Water Scrubbing Innovations for Biogas
  • Chemical Absorption Breakthroughs
  • Small-Scale Biogas Upgrading Systems
  • Impact of Biogas Upgrading on Greenhouse Gas Emissions
  • Community-Level Biogas Utilization Projects
  • Integration of Biogas Upgrading in Sustainable Agriculture Practices

Sample Global Startups and Companies

  1. Bright Biomethane:
    • Technology Enhancement: Bright Biomethane specializes in biogas upgrading solutions, which involve the purification of raw biogas into high-purity biomethane. Their technology utilizes advanced membrane separation or pressure swing adsorption (PSA) processes to remove impurities such as carbon dioxide, hydrogen sulfide, and moisture from biogas, resulting in a clean and high-quality fuel product.
    • Uniqueness: Bright Biomethane’s unique selling point lies in their focus on providing turnkey biogas upgrading solutions that are highly efficient, cost-effective, and reliable. Their systems are modular and scalable, allowing for easy integration into existing biogas plants of various sizes. Additionally, they offer remote monitoring and control capabilities, ensuring optimal performance and minimal downtime.
    • End-User Segments: Bright Biomethane serves a diverse range of end-user segments, including agricultural, municipal, industrial, and wastewater treatment facilities that generate biogas as a byproduct of anaerobic digestion processes. Their solutions enable these facilities to upgrade biogas to biomethane, which can be injected into the natural gas grid, used as vehicle fuel, or utilized for combined heat and power generation.
  2. Xebec Adsorption Inc.:
    • Technology Enhancement: Xebec Adsorption Inc. specializes in gas purification and separation technologies, including biogas upgrading systems. Their solutions typically involve pressure swing adsorption (PSA) or vacuum swing adsorption (VSA) processes, which selectively remove impurities such as carbon dioxide, hydrogen sulfide, and siloxanes from biogas, resulting in high-purity biomethane.
    • Uniqueness: Xebec Adsorption Inc. stands out for its expertise in designing and manufacturing custom-tailored biogas upgrading systems to meet the specific needs and challenges of different biogas projects. Their solutions are highly efficient, reliable, and environmentally sustainable, helping to reduce greenhouse gas emissions and reliance on fossil fuels.
    • End-User Segments: Xebec Adsorption Inc. serves a wide range of end-user segments, including agricultural, municipal, industrial, and landfill gas applications. Their biogas upgrading systems enable these facilities to convert biogas into biomethane for injection into the natural gas grid, use as vehicle fuel, or conversion into renewable electricity and heat.
  3. Greenlane Renewables:
    • Technology Enhancement: Greenlane Renewables specializes in biogas upgrading solutions, focusing on pressure swing adsorption (PSA) and water scrubbing technologies to purify raw biogas into high-quality biomethane. Their systems remove impurities such as carbon dioxide, hydrogen sulfide, and moisture, resulting in a clean and renewable fuel product suitable for various applications.
    • Uniqueness: Greenlane Renewables is known for its innovative and customizable biogas upgrading solutions, which are designed to maximize efficiency, flexibility, and reliability. They offer a range of modular systems that can be easily integrated into new or existing biogas plants, allowing for scalability and cost-effectiveness. Additionally, their solutions are backed by extensive technical expertise and ongoing support services.
    • End-User Segments: Greenlane Renewables serves a diverse range of end-user segments, including agricultural, municipal, industrial, and landfill gas projects. Their biogas upgrading systems enable these facilities to convert biogas into biomethane for injection into the natural gas grid, use as vehicle fuel, or utilization in combined heat and power applications, helping to decarbonize energy production and reduce environmental impact.

Sample Research At Top-Tier Universities

  1. Wageningen University & Research:
    • Research Focus: Wageningen University & Research is a leader in the field of Biogas Upgrading and Utilization, focusing on developing advanced technologies for upgrading biogas to biomethane and its utilization in various energy and industrial applications.
    • Uniqueness: Their research involves the optimization of biogas purification processes, including pressure swing adsorption (PSA), water scrubbing, and membrane separation, to produce high-purity biomethane suitable for injection into the natural gas grid or use as a transport fuel. They also explore innovative applications of biomethane, such as combined heat and power (CHP) generation, vehicle fueling stations, and feedstock for bio-based chemical production.
    • End-use Applications: The outcomes of their work find applications in wastewater treatment plants, agricultural biogas facilities, and municipal solid waste management systems, enabling the conversion of organic waste into renewable energy and value-added products. By advancing Biogas Upgrading and Utilization technologies, Wageningen’s research contributes to reducing greenhouse gas emissions, improving energy security, and promoting circular economy principles.
  2. Technical University of Denmark (DTU):
    • Research Focus: Technical University of Denmark (DTU) conducts pioneering research on Biogas Upgrading and Utilization, leveraging its expertise in chemical engineering, catalysis, and renewable energy systems to develop innovative processes for upgrading biogas and enhancing its economic viability.
    • Uniqueness: Their research encompasses the development of novel catalyst materials, reactor designs, and process intensification techniques for methane enrichment, carbon dioxide removal, and hydrogen sulfide scrubbing in biogas upgrading units. They also investigate the integration of biomethane production with anaerobic digestion, biofuels synthesis, and carbon capture and utilization (CCU) technologies to maximize resource recovery and minimize environmental impact.
    • End-use Applications: The outcomes of their work have applications in agricultural biogas plants, landfill gas recovery projects, and industrial waste treatment facilities, enabling the production of clean and renewable biogas for heat, power, and transportation. By advancing Biogas Upgrading and Utilization technologies, DTU’s research supports the transition to a low-carbon energy system and the development of sustainable bioeconomies.
  3. University of California, Davis:
    • Research Focus: University of California, Davis is engaged in innovative research on Biogas Upgrading and Utilization, focusing on developing scalable and cost-effective solutions for upgrading biogas to biomethane and its integration into decentralized energy systems.
    • Uniqueness: Their research involves the integration of anaerobic digestion with biogas upgrading technologies, such as pressure swing adsorption (PSA), water scrubbing, and membrane separation, to produce renewable natural gas with high methane content and low impurity levels. They also explore co-digestion strategies, feedstock pre-treatment methods, and digester optimization techniques to enhance biogas production efficiency and feedstock flexibility.
    • End-use Applications: The outcomes of their work find applications in agricultural waste management, food processing industries, and decentralized biogas-to-energy projects, providing renewable energy solutions for rural communities, off-grid facilities, and remote areas. By developing innovative Biogas Upgrading and Utilization technologies, UC Davis’s research contributes to mitigating climate change, improving air quality, and fostering sustainable development.

commercial_img Commercial Implementation

Biogas upgrading technologies are widely implemented in commercial-scale biogas plants around the world. Biomethane is being injected into natural gas pipelines, used as a transportation fuel, and used for electricity generation.