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Reducing Industrial CO2 Emissions with Energy-Efficiency Improvement

Posted August 7, 2024 | Sustainability |
Reducing Industrial CO2 Emissions with Energy-Efficiency Improvement

Energy-efficiency improvement is a feasible, low-cost approach that, in most cases, does not require any major change to industrial processes and can bring immediate emissions reductions. Since 2010, through the Better Buildings, Better Plants program, the US Department of Energy (DOE) has worked with more than 270 manufacturers and water and wastewater utilities across the US to accelerate the adoption of energy-efficient practices, highlight innovative technologies, and spur change at an organizational level.

Through the program, DOE supports 3,600 facilities, corresponding to 14% of US manufacturers. Collectively, these firms have reported savings of 2.2 quadrillion BTUs (British thermal units) of energy. That is equivalent to 131 million metric tons (MMT) of CO2 emissions reductions and a savings of US $10.6 billion.

Figure 1 shows the average energy-intensity improvement in terms of the number of plants and the program’s energy footprint for selected sectors since 2010. Current energy-efficiency measures in the US industrial sector can potentially save 6.25 quads of energy (6.5% of baseline energy use in 2050) and reduce CO2 emissions by 244 MMT (5.6% of baseline energy CO2 emissions in 2050) through 2050.

Figure 1. Average energy-intensity improvement in terms of number of plants and program energy footprint for selected sectors (source: DOE)
Figure 1. Average energy-intensity improvement in terms of number of plants and program energy footprint for selected sectors (source: DOE)

Similar studies have been conducted around the world. In 2015, the UK government released a series of reports that assessed the potential for a low-carbon future and developed decarbonization roadmaps for eight of the UK’s most heat-intensive industrial sectors. Per the study, combined max tech pathways (CCUS, electrification, material efficiency, energy efficiency, and other approaches) can reduce emissions from 81 MMT CO2 in 2012 to 22 MMT CO2 in 2050. Energy efficiency combined with heat recovery alone potentially contributes to a reduction in total emissions of 8 MMT CO2 (13% of the overall reduction) in 2050. The main contributors to emissions reductions are the refining industry (43%), the pulp and paper industry (41%), and the food and beverage industry (36%).

Similarly, industrial energy consumption in the EU is projected to drop by 25% in 2050 compared to 2015 levels through energy-efficiency improvements, with waste heat–recovery applications as the primary driver. The energy-efficiency improvements are also expected to reduce energy-related CO2 emissions by 22% in iron and steel sectors, 22% in chemical sectors, 35% in the nonmetallic minerals (e.g., cement, lime) sector, 15% in the nonferrous metals sector, and 32% in refineries in 2050 compared with the baseline scenario. In Australia, energy efficiency in the manufacturing sector could cause a 40% reduction in energy intensity by 2050 compared to 2010 levels.

[For more from the authors on this topic, see: “Energy Efficiency’s Role in Industrial Decarbonization.”]

About The Author
Senthil Kumar Sundaramoorthy
Senthil Sundaramoorthy is R&D Associate Staff Member in the Manufacturing Energy Efficiency Research & Analysis Group at Oak Ridge National Laboratory (ORNL) with 12+ years’ experience managing and applying best practices in industrial and commercial energy systems. Mr. Kumar provides technical support to US Department of Energy (DOE) Better Plants and Better Climate Challenge partners in collaboration with the DOE’s Advanced… Read More
Dipti Kamath
Dipti Kamath is R&D Associate Staff Member in the Manufacturing Energy Efficiency Research & Analysis Group at Oak Ridge National Laboratory (ORNL). She works on the techno-economic and lifecycle assessment of integrated biorefinery technologies for the paper and pulp industries, as well as biomass allocation optimization. Dr. Kamath also serves as a Technical Account Manager for the US Department of Energy (DOE) Better Buildings, Better… Read More
Sachin Nimbalkar
Sachin Nimbalkar leads the Manufacturing Energy Efficiency Research & Analysis Group at Oak Ridge National Laboratory (ORNL). He has 15+ years’ experience, including working as a Senior R&D Staff Member at ORNL. Dr. Nimbalkar’s team focuses on researching and disseminating knowledge as well as developing impactful practices, tools, and technologies relating to energy, water, and material efficiency in manufacturing. He supports US… Read More
Christopher Price
Christopher Price is R&D Associate Staff Member in the Manufacturing Energy Efficiency Research and Analysis Group at Oak Ridge National Laboratory (ORNL), where he serves as Technical Account Manager for US Department of Energy (DOE) Better Buildings, Better Plants program. Dr. Price assists companies in baselining and tracking energy consumption and implementing cost-effective energy management programs for their facilities. He contributes… Read More
Thomas Wenning
Thomas Wenning is Program Manager for industrial energy efficiency at Oak Ridge National Laboratory (ORNL), where he manages both domestic and international industrial energy-efficiency technology assistance and deployment activities. Mr. Wenning supports the US Department of Energy (DOE) Better Buildings, Better Plants program and the Federal Energy Management Program by providing technical assistance, energy assessments, training, and energy… Read More
Joe Cresko
Joe Cresko is Chief Engineer for the Industrial Efficiency & Decarbonization Office at the US Department of Energy (DOE) Office of Energy Efficiency and Renewable Energy (EERE), leading the strategic analysis team, which helps assess the lifecycle and cross-sector impacts of new manufacturing advances. Mr. Cresko first joined EERE in the Advanced Manufacturing Office (AMO) as an American Association for the Advancement of Science (AAAS)… Read More