The chemical manufacturing industry is the most energy intensive subsector within the manufacturing sector in the United States. As of 2018, the chemical industry consumed 3.8 quadrillion British thermal units of fuel and 4.3 quadrillion British thermal units of non-fuel in order to power its production. There are six industries responsible for the majority of energy consumption - chemicals, petroleum and coal products, paper, primary metals, food, and nonmetallic mineral products.

China Energy Consumption: Industry data was reported at 3,637.820 SCE Ton mn in 2022. This records an increase from the previous number of 3,485.510 SCE Ton mn for 2021. China Energy Consumption: Industry data is updated yearly, averaging 1,393.498 SCE Ton mn from Dec 1980 (Median) to 2022, with 39 observations. The data reached an all-time high of 3,637.820 SCE Ton mn in 2022 and a record low of 389.860 SCE Ton mn in 1980. China Energy Consumption: Industry data remains active status in CEIC and is reported by National Bureau of Statistics. The data is categorized under Global Database’s China – Table CN.RBB: Energy Consumption.

Industrial Energy End Use in the U.S

Facility-Level Combustion Energy Data

By US Open Data Portal, data.gov [source]

About this dataset

This dataset contains in-depth facility-level information on industrial combustion energy use in the United States. It provides an essential resource for understanding consumption patterns across different sectors and industries, as reported by large emitters (>25,000 metric tons CO2e per year) under the U.S. EPA's Greenhouse Gas Reporting Program (GHGRP). Our records have been calculated using EPA default emissions factors and contain data on fuel type, location (latitude, longitude), combustion unit type and energy end use classified by manufacturing NAICS code. Additionally, our dataset reveals valuable insight into the thermal spectrum of low-temperature energy use from a 2010 Energy Information Administration Manufacturing Energy Consumption Survey (MECS). This information is critical to assessing industrial trends of energy consumption in manufacturing sectors and can serve as an informative baseline for efficient or renewable alternative plans of operation at these facilities. With this dataset you're just a few clicks away from analyzing research questions related to consumption levels across industries, waste issues associated with unconstrained fossil fuel burning practices and their environmental impacts

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How to use the dataset

This dataset provides detailed information on industrial combustion energy end use in the United States. Knowing how certain industries use fuel can be valuable for those interested in reducing energy consumption and its associated environmental impacts.

• To make the most out of this dataset, users should first become familiar with what's included by looking at the columns and their respective definitions. After becoming familiar with the data, users should start to explore areas of interest such as Fuel Type, Report Year, Primary NAICS Code, Emissions Indicators etc. The more granular and specific details you can focus on will help build a stronger analysis from which to draw conclusions from your data set.

• Next steps could include filtering your data set down by region or end user type (such as direct related processes or indirect support activities). Segmenting your data set further can allow you to identify trends between fuel type used in different regions or compare emissions indicators between different processes within manufacturing industries etc. By taking a closer look through this lens you may be able to find valuable insights that can help inform better decision making when it comes to reducing energy consumption throughout industry in both public and private sectors alike.

• if exploring specific trends within industry is not something that’s of particular interest to you but rather understanding general patterns among large emitters across regions then it may be beneficial for your analysis to group like-data together and take averages over larger samples which better represent total production across an area or multiple states (timeline varies depending on needs). This approach could open up new possibilities for exploring correlations between economic productivity metrics compared against industrial energy use over periods of time which could lead towards more formal investigations about where efforts are being made towards improved resource efficiency standards among certain industries/areas of production compared against other more inefficient sectors/regionsetc — all from what's already present here!

By leveraging the information provided within this dataset users have access to many opportunities for finding all sorts of interesting yet practical insights which can have important impacts far beyond understanding just another singular statistic alone; so happy digging!

Research Ideas

• Analyzing the trends in combustion energy uses by region across different industries.
• Predicting the potential of transitioning to clean and renewable sources of energy considering the current end-uses and their magnitude based on this data.
• Creating an interactive web map application to visualize multiple industrial sites, including their energy sources and emissions data from this dataset combined with other sources (EPA’s GHGRP, MECS survey, etc)

Acknowledgements

If you use this dataset in your research, please credit the original authors. Data Source

License

**License: [CC0 1.0 Universal (CC0 1.0) - Public Domain Dedication](https://creativecommons...

In the fiscal year 2022, the final energy consumption of the manufacturing sector in Japan amounted to approximately five thousand petajoules, down from over six thousand petajoules in fiscal year 2013.

Data are presented at the national level by fuel type in gigajoules (butane, electricity, steam, etc) and by North American Industry Classification System (NAICS). Not all combinations are available.

In the fiscal year 2022, the final energy consumption of the manufacturing sector in Japan amounted to approximately 1.12 thousand petajoules from electricity. The final energy consumption from electricity has decreased compared to around 1.27 thousand petajoules in fiscal 2013. Within the business sector, the manufacturing industry was the leading consumer of energy in Japan.

Data are presented at the national level, by fuel type (butane, electricity, steam, etc) and by North American Industry Classification System (NAICS). Not all combinations are available.

China Energy Consumption: Industry: Mfg: Automobile data was reported at 47.810 SCE Ton mn in 2022. This records an increase from the previous number of 46.450 SCE Ton mn for 2021. China Energy Consumption: Industry: Mfg: Automobile data is updated yearly, averaging 33.800 SCE Ton mn from Dec 2012 (Median) to 2022, with 11 observations. The data reached an all-time high of 47.810 SCE Ton mn in 2022 and a record low of 27.696 SCE Ton mn in 2012. China Energy Consumption: Industry: Mfg: Automobile data remains active status in CEIC and is reported by National Bureau of Statistics. The data is categorized under China Premium Database’s Energy Sector – Table CN.RBB: Energy Consumption.

In 2022, the total energy consumption of electricity in the manufacturing sector in Thailand amounted to approximately 6.88 million tons of oil equivalent. In that year, the total energy consumption reached about 32.18 million tons of oil equivalent.

China Energy Consumption: Industry: Mfg: Paper Making data was reported at 44.620 SCE Ton mn in 2022. This records an increase from the previous number of 42.040 SCE Ton mn for 2021. China Energy Consumption: Industry: Mfg: Paper Making data is updated yearly, averaging 36.124 SCE Ton mn from Dec 1985 (Median) to 2022, with 37 observations. The data reached an all-time high of 46.866 SCE Ton mn in 2009 and a record low of 12.950 SCE Ton mn in 1985. China Energy Consumption: Industry: Mfg: Paper Making data remains active status in CEIC and is reported by National Bureau of Statistics. The data is categorized under China Premium Database’s Energy Sector – Table CN.RBB: Energy Consumption.

Global Energy Consumption in Industry by Country, 2023 Discover more data with ReportLinker!

Facility-level industrial combustion energy use is calculated from greenhouse gas emissions data reported by large emitters (>25,000 metric tons CO2e per year) under the U.S. EPA's Greenhouse Gas Reporting Program (GHGRP, https://www.epa.gov/ghgreporting). The calculation applies EPA default emissions factors to reported fuel use by fuel type. Additional facility information is included with calculated combustion energy values, such as industry type (six-digit NAICS code), location (lat, long, zip code, county, and state), combustion unit type, and combustion unit name. Further identification of combustion energy use is provided by calculating energy end use (e.g., conventional boiler use, co-generation/CHP use, process heating, other facility support) by manufacturing NAICS code. Manufacturing facilities are matched by their NAICS code and reported fuel type with the proportion of combustion fuel energy for each end use category identified in the 2010 Energy Information Administration Manufacturing Energy Consumption Survey (MECS, http://www.eia.gov/consumption/manufacturing/data/2010/). MECS data are adjusted to account for data that were withheld or whose end use was unspecified following the procedure described in Fox, Don B., Daniel Sutter, and Jefferson W. Tester. 2011. The Thermal Spectrum of Low-Temperature Energy Use in the United States, NY: Cornell Energy Institute.

This table contains figures on the supply and consumption of energy broken down by sector and by energy commodity. The energy supply is equal to the indigenous production of energy plus the receipts minus the deliveries of energy plus the stock changes. Consumption of energy is equal to the sum of own use, distribution losses, final energy consumption, non-energy use and the total net energy transformation. For each sector, the supply of energy is equal to the consumption of energy.

For some energy commodities, the total of the observed domestic deliveries is not exactly equal to the sum of the observed domestic receipts. For these energy commodities, a statistical difference arises that can not be attributed to a sector.

The breakdown into sectors follows mainly the classification as is customary in international energy statistics. This classification is based on functions of various sectors in the energy system and for several break downs on the international Standard Industrial Classification (SIC). There are two main sectors: the energy sector (companies with main activity indigenous production or transformation of energy) and energy consumers (other companies, vehicles and dwellings). In addition to a breakdown by sector, there is also a breakdown by energy commodity, such as coal, various petroleum products, natural gas, renewable energy, electricity and heat and other energy commodities like non renewable waste.

The definitions used in this table are exactly in line with the definitions in the Energy Balance table; supply, transformation and consumption. That table does not contain a breakdown by sector (excluding final energy consumption), but it does provide information about imports, exports and bunkering and also provides more detail about the energy commodities.

Data available: From: 1990.

Status of the figures: Figures up to and including 2022 are definite. Figures for 2023 and 2024 are revised provisional.

Changes as of June 2025: Figures for 2024 have been updated.

Changes as of March 17th 2025: For all reporting years the underlying code for 'Total crudes, fossil fraction' and 'Total kerosene, fossiel fraction' is adjusted. Figures have not been changed.

Changes as of November 15th 2024: The structure of the table has been adjusted. The adjustment concerns the division into sectors, with the aluminum industry now being distinguished separately within the non-ferrous metal sector. This table has also been revised for 2015 to 2021 as a result of new methods that have also been applied for 2022 and 2023. This concerns the following components: final energy consumption of LPG, distribution of final energy consumption of motor gasoline, sector classification of gas oil/diesel within the services and transfer of energy consumption of the nuclear industry from industry to the energy sector. The natural gas consumption of the wood and wood products industry has also been improved so that it is more comparable over time. This concerns changes of a maximum of a few PJ.

Changes as of June 7th 2024: Revised provisional figures of 2023 have been added.

Changes as of April 26th of 2024 The energy balance has been revised for 2015 and later on a limited number of points. The most important is the following: 1. For solid biomass and municipal waste, the most recent data have been included. Furthermore data were affected by integration with figures for a new, yet to be published StatLine table on the supply of solid biomass. As a result, there are some changes in receipts of energy, deliveries of energy and indigenous production of biomass of a maximum of a few PJ. 2. In the case of natural gas, an improvement has been made in the processing of data for stored LNG, which causes a shift between stock changes, receipts of energy and deliveries of energy of a maximum of a few PJ.

Changes as of March 25th of 2024: The energy balance has been revised and restructured. This concerns mainly the following: 1. Different way of dealing with biofuels that have been mixed with fossil fuels 2. A breakdown of the natural gas balance of agriculture into greenhouse horticulture and other agriculture. 3. Final consumption of electricity in services

1. Blended biofuels Previously, biofuels mixed with fossil fuels were counted as petroleum crude and products. In the new energy balance, blended biofuels count for renewable energy and petroleum crude and products and the underlying products (such as gasoline, diesel and kerosene) only count the fossil part of mixtures of fossil and biogenic fuels. To make this clear, the names of the energy commodities have been changed. The consequence of this adjustment is that part of the energy has been moved from petroleum to renewable. The energy balance remains the same for total energy commodities. The aim of this adjustment is to make the increasing role of blended biofuels in the Energy Balance visible and to better align with the Energy Balances published by Eurostat and the International Energy Agency. Within renewable energy, biomass, liquid biomass is now a separate energy commodity. This concerns both pure and blended biofuels.

2. Greenhouse horticulture separately The energy consumption of agriculture in the Netherlands largely takes place in greenhouse horticulture. There is therefore a lot of attention for this sector and the need for separate data on energy consumption in greenhouse horticulture. To meet this need, the agriculture sector has been divided into two subsectors: Greenhouse horticulture and other agriculture. For the time being, we only publish separate natural gas figures for greenhouse horticulture.

3. Higher final consumption of electricity in services in 2021 and 2022. The way in which electric road transport is treated has improved, resulting in an increase in the supply and final consumption of electricity in services by more than 2 PJ in 2021 and 2022. This also works through the supply of electricity in sector H (Transport and storage).

Changes as of November 14th 2023: Figures for 2021 and 2022 haven been adjusted. Figures for the Energy Balance for 2015 to 2020 have been revised regarding the following items: - For 2109 and 2020 final consumption of heat in agriculture is a few PJ lower and for services a few PJ higher. This is the result of improved interpretation of available data in supply of heat to agriculture. - During the production of geothermal heat by agriculture natural gas is produced as by-product. Now this is included in the energy balance. The amount increased from 0,2 PJ in 2015 to 0,7 PJ in 2020. - There are some improvements in the data for heat in industry with a magnitude of about 1 PJ or smaller. - There some other improvements, also about 1 PJ or smaller.

Changes as of June 15th 2023: Revised provisional figures of 2022 have been added.

Changes as of December 15th 2022: Figures for 1990 up to and including 2019 have been revised. The revision mainly concerns the consumption of gas- and diesel oil and energy commodities higher in the classification (total petroleum products, total crude and petroleum produtcs and total energy commodities). The revision is twofold: - New data for the consumption of diesel oil in mobile machine have been incorporated. Consequently, the final energy consumption of gas- and diesel oil in construction, services and agriculture increases. The biggest change is in construction (+10 PJ from 1990-2015, decreasing to 1 PJ in 2019. In agriculture the change is about 0.5-1.5 PJ from 2010 onwards and for services the change is between 0 and 3 PJ for the whole period. - The method for dealing with the statistical difference has been adapted. Earlier from 2013 onwards a difference of about 3 percent was assumed, matching old data (up to and including 2012) on final consumption of diesel for road transport based on the dedicated tax specifically for road that existed until 2012. In the new method the statistical difference is eliminated from 2015 onwards. Final consumption of road transport is calculated as the remainder of total supply to the market of diesel minus deliveries to users other than road transport. The first and second item affect both final consumption of road transport that decreases consequently about 5 percent from 2015 onwards. Before the adaption of the tax system for gas- and diesel oil in 2013 the statistical difference was positive (more supply than consumption). With the new data for mobile machines total consumption has been increased and the statistical difference has been reduced and is even negative for a few years.

Changes as of 1 March 2022: Figures for 1990 up to and including 2020 have been revised. The most important change is a different way of presenting own use of electricity of power-generating installations. Previously, this was regarded as electricity and CHP transformation input. From now on, this is seen as own use, as is customary in international energy statistics. As a result, the input and net energy transformation decrease and own use increases, on average about 15 PJ per year. Final consumers also have power generating installations. That's why final consumers now also have own use, previously this was not so. In the previous revision of 2021, the new sector blast furnaces was introduced for the years 2015 up to and including 2020, which describes the transformation of coke oven coke and coking coal into blast furnace gas that takes place in the production of pig iron from iron ore. This activity was previously part of the steel industry. With this revision, the change has been put back to 1990.

When will new figures be published? Revised provisional figures: June/July of the following year. Definite figures: December of the second following year.

Energy Consumption in Manufacturing Sector based on Sub-Sectors in Peninsular Malaysia from 2010 until 2016 according to Type of Fuels in ktoe

CN: Electricity Consumption: Industry: Mfg: Other Mfg data was reported at 77.819 kWh bn in 2022. This records an increase from the previous number of 74.239 kWh bn for 2021. CN: Electricity Consumption: Industry: Mfg: Other Mfg data is updated yearly, averaging 48.213 kWh bn from Dec 2012 (Median) to 2022, with 11 observations. The data reached an all-time high of 77.819 kWh bn in 2022 and a record low of 41.624 kWh bn in 2013. CN: Electricity Consumption: Industry: Mfg: Other Mfg data remains active status in CEIC and is reported by National Bureau of Statistics. The data is categorized under China Premium Database’s Energy Sector – Table CN.RBB: Electricity Consumption: by Industry.

CN: Electricity Consumption: Industry: Mining: Non Ferrous Metal data was reported at 33.955 kWh bn in 2022. This records an increase from the previous number of 32.735 kWh bn for 2021. CN: Electricity Consumption: Industry: Mining: Non Ferrous Metal data is updated yearly, averaging 21.572 kWh bn from Dec 1994 (Median) to 2022, with 29 observations. The data reached an all-time high of 38.617 kWh bn in 2019 and a record low of 6.654 kWh bn in 1998. CN: Electricity Consumption: Industry: Mining: Non Ferrous Metal data remains active status in CEIC and is reported by China Electricity Council. The data is categorized under China Premium Database’s Energy Sector – Table CN.RBB: Electricity Consumption: by Industry.

These tables provide details of energy consumption and energy intensity for the Manufacturing sector as a whole, as well as for the seven most energy-consuming subsectors. They also compare energy sources used in the sector from 1995 to 2014.

Forecast: Energy Consumption in Industry in the US 2023 - 2027 Discover more data with ReportLinker!

CN: Electricity Consumption: ytd: SI: Industry: Heavy data was reported at 3,660.671 kWh bn in Dec 2017. This records an increase from the previous number of 3,264.300 kWh bn for Nov 2017. CN: Electricity Consumption: ytd: SI: Industry: Heavy data is updated monthly, averaging 1,469.835 kWh bn from Feb 2007 (Median) to Dec 2017, with 129 observations. The data reached an all-time high of 3,660.671 kWh bn in Dec 2017 and a record low of 211.000 kWh bn in Jan 2012. CN: Electricity Consumption: ytd: SI: Industry: Heavy data remains active status in CEIC and is reported by China Electricity Council. The data is categorized under China Premium Database’s Energy Sector – Table CN.RBB: Electricity Consumption: by Industry.

Colombia Electricity Consumption: Mfg: Other Manufacturing Industries data was reported at 214.197 kWh mn in 2017. This records a decrease from the previous number of 224.017 kWh mn for 2016. Colombia Electricity Consumption: Mfg: Other Manufacturing Industries data is updated yearly, averaging 219.006 kWh mn from Dec 2015 (Median) to 2017, with 3 observations. The data reached an all-time high of 224.017 kWh mn in 2016 and a record low of 214.197 kWh mn in 2017. Colombia Electricity Consumption: Mfg: Other Manufacturing Industries data remains active status in CEIC and is reported by National Statistics Administrative Department. The data is categorized under Global Database’s Colombia – Table CO.RB006: Electricity Consumption: Manufacturing Sector.