ENERGY DEPARTMENT INVESTS $28 MILLION TO ADVANCE CLEANER FOSSIL FUEL–BASED POWER GENERATION
August 24, 2016 – The U.S. Department of Energy (DOE) today announced the selection of 14 research and development projects to advance energy systems that will enable cost-competitive, fossil fuel–based power generation with near-zero emissions. The new projects, which span 11 states, will accelerate the scale-up of coal-based advanced combustion power systems, advance coal gasification processes, and improve the cost, reliability, and endurance of solid oxide fuel cells. The total award value of the projects exceeds $36 million, which includes a federal investment of more than $28 million and recipient cost-sharing of $8.4 million. Read More!
Researchers Uncover Copper’s Potential for Reducing CO2 Emissions in Chemical Looping
Researchers at the Department of Energy’s National Energy Technology Laboratory (NETL) believe that when used as a part of a promising coal combustion technology known as chemical looping, copper can help economically remove carbon dioxide (CO2) from fossil fuel emissions. Read More!
| Advanced Combustion is an Alternative for Post-Combustion Carbon Capture…
Advanced Combustion technologies separate gases at the front end of the power generation process as a cost competitive alternative to post-combustion capture.
Advanced combustion power generation combusts fossil fuels in a high-oxygen (O2) concentration environment rather than air. This eliminates most, if not all, of the nitrogen (N2) found in air from the combustion process, resulting in flue gas composed of CO2, water (H2O), contaminants from the fuel (including coal ash), and other gases that infiltrated the combustion system. The high concentration of CO2 (≈70 percent) and absence of nitrogen simplify separation of CO2 from the flue gas for storage or beneficial use. Thus, oxygen-fired combustion is an alternative approach to post-combustion capture for carbon capture and storage (CCS) for coal-fired systems. However, the appeal of oxygen-fired combustion is tempered several challenges, namely capital cost, energy consumption, operational challenges of supplying O2 to the combustion system, air infiltration that dilutes the flue gas with N2, and excess O2 that must be removed from the concentrated CO2 stream. These factors mean oxygen-fired combustion systems are not affordable at their current level
of development. Advanced combustion system performance can be improved by two means: (1) by lowering the cost of oxygen supplied to the system and (2) by increasing the overall system efficiency. The Advanced Combustion Systems Program targets both of these possible improvements through sponsored cost-shared research into three key technologies: (1) Oxy-combustion, (2) Chemical Looping Combustion (CLC), and (3) Enabling Technologies/Innovative Concepts.
NETL is funding projects within each of the above-mentioned approaches. These R&D efforts are being performed both externally by industry, research organizations, and academic institutions, and internally through NETL’s Office of Research and Development (ORD).