SwRI, U-Michigan (U.S.) engineers create more effective burner to reduce methane emissions
- Study shows burner eliminates significant amounts of methane encountered during oil production
Researchers at Southwest Research Institute (SwRI) and the University of Michigan (U-M) have published a new study showing an advanced new methane flare burner, created with additive manufacturing and machine learning, eliminates 98% of methane vented during oil production. The burner was designed by U-M engineering researchers and tested at SwRI.
Oil producers can generate methane during oil production and typically use flare stacks to burn off this gas. However, wind blowing across conventional open flame burners reduces their effectiveness, releasing 40% or more of methane into the atmosphere. Over 100 years, methane has 28 times greater global warming potential than carbon dioxide (CO2) and is 84 times more potent on a 20-year timescale. Flaring reduces overall global warming potential, but ineffective flaring dampens this strategy.
SwRI collaborated with U-M engineers to leverage machine-learning, computational fluid dynamics (CFD) and additive manufacturing to create and test a burner with high methane destruction efficiency and combustion stability at the challenging conditions present in the field.
“We tested the burner at an indoor facility at SwRI, where we could control the crosswind and measure burner efficiency under different conditions,” said SwRI Principal Engineer Alex Schluneker, one of the paper’s co-authors. “Even the slightest amount of crosswind significantly reduced the effectiveness of most burners. We found that the structure and motions of the fins inside the burner were essential for maintaining efficiency. The U-M team engineered it to significantly improve performance.”
The burner has a complex nozzle base that splits the flow of methane in three different directions. The impeller design guides the gas toward the flame. This novel design allows for the even mixing of oxygen and methane and provides time for the combustion to occur before crosswinds can affect it. This design is key to the burner’s efficiency.
“A good ratio of oxygen to methane is key to combustion,” said SwRI Senior Research Engineer Justin Long. “The surrounding air needs to be captured and incorporated to mix with the methane, but too much can dilute it. U-M researchers conducted a lot of computational fluid dynamics work to find a design with an optimal air-methane balance, even when subjected to high-crosswind conditions.”
SwRI and U-M teams are continuing to collaborate on creating and testing new burner designs, aiming to create an even more efficient and cost-effective prototype in 2025.
The project is supported by the U.S. Department of Energy’s Advanced Research Projects Agency–Energy (ARPA—E) Reducing Emissions of Methane Every Day of the Year (REMEDY) program. It is one of several projects funded to support the U.S. Methane Emissions Reduction Action Plan, announced at the 2021 United Nations Climate Change Conference (COP26). The plan seeks to reduce methane emissions and promote American innovation, developing new technologies to achieve climate goals.
The information, data, or work presented herein was funded in part by the Advanced Research Projects Agency-Energy (ARPA-E), U.S. Department of Energy, under Award Number DE-AR0001534.
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