United States Electricity Consumption data was reported at 10.243 kWh/Day bn in Mar 2025. This records a decrease from the previous number of 11.765 kWh/Day bn for Feb 2025. United States Electricity Consumption data is updated monthly, averaging 9.940 kWh/Day bn from Jan 1991 (Median) to Mar 2025, with 411 observations. The data reached an all-time high of 13.179 kWh/Day bn in Jul 2024 and a record low of 7.190 kWh/Day bn in Apr 1991. United States Electricity Consumption data remains active status in CEIC and is reported by U.S. Energy Information Administration. The data is categorized under Global Database’s United States – Table US.RB004: Electricity Supply and Consumption. [COVID-19-IMPACT]

The City and County Energy Profiles lookup table provides modeled electricity and natural gas consumption and expenditures, on-road vehicle fuel consumption, vehicle miles traveled, and associated emissions for each U.S. city and county. Please note this data is modeled and more precise data may be available from regional, state, or other sources. The modeling approach for electricity and natural gas is described in Sector-Specific Methodologies for Subnational Energy Modeling: https://www.nrel.gov/docs/fy19osti/72748.pdf. This data is part of a suite of state and local energy profile data available at the "State and Local Energy Profile Data Suite" link below and complements the wealth of data, maps, and charts on the State and Local Planning for Energy (SLOPE) platform, available at the "Explore State and Local Energy Data on SLOPE" link below. Examples of how to use the data to inform energy planning can be found at the "Example Uses" link below.

Whether you wonder to know how's the electricity demand is evolving in the US during the year or you would like to know how's the electricity mix has evolved through time, that's the dataset for you!

Energy is always something we have taken for granted, but in recent years with all the bottlenecks and geopolitical problems that have followed one another, it has become an increasingly central theme.

Directly pulled off from the EIA API, in this Kaggle dataset you can find hourly data about the energy production by each source in the US.

Possible Data science problems: - EDA - Energy demand forecasting - Electricity production forecasting by source - and many more

Note: This dataset has been superseded by the dataset found at "End-Use Load Profiles for the U.S. Building Stock" (submission 4520; linked in the submission resources), which is a comprehensive and validated representation of hourly load profiles in the U.S. commercial and residential building stock. The End-Use Load Profiles project website includes links to data viewers for this new dataset. For documentation of dataset validation, model calibration, and uncertainty quantification, see Wilson et al. (2022).

These data were first created around 2012 as a byproduct of various analyses of solar photovoltaics and solar water heating (see references below for are two examples). This dataset contains several errors and limitations. It is recommended that users of this dataset transition to the updated version of the dataset posted in the resources. This dataset contains weather data, commercial load profile data, and residential load profile data.

Weather The Typical Meteorological Year 3 (TMY3) provides one year of hourly data for around 1,000 locations. The TMY weather represents 30-year normals, which are typical weather conditions over a 30-year period.

Commercial The commercial load profiles included are the 16 ASHRAE 90.1-2004 DOE Commercial Prototype Models simulated in all TMY3 locations, with building insulation levels changing based on ASHRAE 90.1-2004 requirements in each climate zone. The folder names within each resource represent the weather station location of the profiles, whereas the file names represent the building type and the representative city for the ASHRAE climate zone that was used to determine code compliance insulation levels. As indicated by the file names, all building models represent construction that complied with the ASHRAE 90.1-2004 building energy code requirements. No older or newer vintages of buildings are represented.

Residential The BASE residential load profiles are five EnergyPlus models (one per climate region) representing 2009 IECC construction single-family detached homes simulated in all TMY3 locations. No older or newer vintages of buildings are represented. Each of the five climate regions include only one heating fuel type; electric heating is only found in the Hot-Humid climate. Air conditioning is not found in the Marine climate region.

One major issue with the residential profiles is that for each of the five climate zones, certain location-specific algorithms from one city were applied to entire climate zones. For example, in the Hot-Humid files, the heating season calculated for Tampa, FL (December 1 - March 31) was unknowingly applied to all other locations in the Hot-Humid zone, which restricts heating operation outside of those days (for example, heating is disabled in Dallas, TX during cold weather in November). This causes the heating energy to be artificially low in colder parts of that climate zone, and conversely the cooling season restriction leads to artificially low cooling energy use in hotter parts of each climate zone. Additionally, the ground temperatures for the representative city were used across the entire climate zone. This affects water heating energy use (because inlet cold water temperature depends on ground temperature) and heating/cooling energy use (because of ground heat transfer through foundation walls and floors). Representative cities were Tampa, FL (Hot-Humid), El Paso, TX (Mixed-Dry/Hot-Dry), Memphis, TN (Mixed-Humid), Arcata, CA (Marine), and Billings, MT (Cold/Very-Cold).

The residential dataset includes a HIGH building load profile that was intended to provide a rough approximation of older home vintages, but it combines poor thermal insulation with larger house size, tighter thermostat setpoints, and less efficient HVAC equipment. Conversely, the LOW building combines excellent thermal insulation with smaller house size, wider thermostat setpoints, and more efficient HVAC equipment. However, it is not known how well these HIGH and LOW permutations represent the range of energy use in the housing stock.

Note that on July 2nd, 2013, the Residential High and Low load files were updated from 366 days in a year for leap years to the more general 365 days in a normal year. The archived residential load data is included from prior to this date.

Electricity consumption in the United States totaled ***** terawatt-hours in 2023, one of the highest values in the period under consideration. Figures represent energy end use, which is the sum of retail sales and direct use of electricity by the producing entity. Electricity consumption in the U.S. is expected to continue increasing in the next decades. Which sectors consume the most electricity in the U.S.? Consumption has often been associated with economic growth. Nevertheless, technological improvements in efficiency and new appliance standards have led to a stabilizing of electricity consumption, despite the increased ubiquity of chargeable consumer electronics. Electricity consumption is highest in the residential sector, followed by the commercial sector. Equipment used for space heating and cooling account for some of the largest shares of residential electricity end use. Leading states in electricity use Industrial hub Texas is the leading electricity-consuming U.S. state. In 2022, the Southwestern state, which houses major refinery complexes and is also home to nearly ** million people, consumed over *** terawatt-hours. California and Florida trailed in second and third, each with an annual consumption of approximately *** terawatt-hours.

The United States is embarking on an ambitious transition to a 100% clean energy economy by 2050, which will require improving the flexibility of electric grids. One way to achieve grid flexibility is to shed or shift demand to align with changing grid needs. To facilitate this, it is critical to understand how and when energy is used. High quality end-use load profiles (EULPs) provide this information, and can help cities, states, and utilities understand the time-sensitive value of energy efficiency, demand response, and distributed energy resources. Publicly available EULPs have traditionally had limited application because of age and incomplete geographic representation. To help fill this gap, the U.S. Department of Energy (DOE) funded a three-year project, End-Use Load Profiles for the U.S. Building Stock, that culminated in this publicly available dataset of calibrated and validated 15-minute resolution load profiles for all major residential and commercial building types and end uses, across all climate regions in the United States. These EULPs were created by calibrating the ResStock and ComStock physics-based building stock models using many different measured datasets, as described in the "Technical Report Documenting Methodology" linked in the submission.

NREL has assembled a list of U.S. retail electricity tariffs and their associated demand charge rates for the Commercial and Industrial sectors. The data was obtained from the Utility Rate Database. Keep the following information in mind when interpreting the data: (1) These data were interpreted and transcribed manually from utility tariff sheets, which are often complex. It is a certainty that these data contain errors, and therefore should only be used as a reference. Actual utility tariff sheets should be consulted if an action requires this type of data. (2) These data only contains tariffs that were entered into the Utility Rate Database. Since not all tariffs are designed in a format that can be entered into the Database, this list is incomplete - it does not contain all tariffs in the United States. (3) These data may have changed since this list was developed (4) Many of the underlying tariffs have additional restrictions or requirements that are not represented here. For example, they may only be available to the agricultural sector or closed to new customers. (5) If there are multiple demand charge elements in a given tariff, the maximum demand charge is the sum of each of the elements at any point in time. Where tiers were present, the highest rate tier was assumed. The value is a maximum for the year, and may be significantly different from demand charge rates at other times in the year. Utility Rate Database: https://openei.org/wiki/Utility_Rate_Database

State-level data on all energy sources. Data on production, consumption, reserves, stocks, prices, imports, and exports. Data are collated from state-specific data reported elsewhere on the EIA website and are the most recent values available. Data on U.S. territories also available.

Google’s energy consumption has increased over the last few years, reaching 25.9 terawatt hours in 2023, up from 12.8 terawatt hours in 2019. The company has made efforts to make its data centers more efficient through customized high-performance servers, using smart temperature and lighting, advanced cooling techniques, and machine learning. Datacenters and energy Through its operations, Google pursues a more sustainable impact on the environment by creating efficient data centers that use less energy than the average, transitioning towards renewable energy, creating sustainable workplaces, and providing its users with the technological means towards a cleaner future for the future generations. Through its efficient data centers, Google has also managed to divert waste from its operations away from landfills. Reducing Google’s carbon footprint Google’s clean energy efforts is also related to their efforts to reduce their carbon footprint. Since their commitment to using 100 percent renewable energy, the company has met their targets largely through solar and wind energy power purchase agreements and buying renewable power from utilities. Google is one of the largest corporate purchasers of renewable energy in the world.

The Utility Energy Registry (UER) is a database platform that provides streamlined public access to aggregated community-scale utility-reported energy data. The UER is intended to promote and facilitate community-based energy planning and energy use awareness and engagement. On April 19, 2018, the New York State Public Service Commission (PSC) issued the Order Adopting the Utility Energy Registry under regulatory CASE 17-M-0315. The order requires utilities under its regulation to develop and report community energy use data to the UER. This dataset includes electricity and natural gas usage data reported at the ZIP Code level collected under a data protocol in effect between 2016 and 2021. Other UER datasets include energy use data reported at the city, town, village, and county level. Data collected after 2021 were collected according to a modified protocol. Those data may be found at https://data.ny.gov/Energy-Environment/Utility-Energy-Registry-Monthly-ZIP-Code-Energy-Us/g2x3-izm4. Data in the UER can be used for several important purposes such as planning community energy programs, developing community greenhouse gas emissions inventories, and relating how certain energy projects and policies may affect a particular community. It is important to note that the data are subject to privacy screening and fields that fail the privacy screen are withheld. The New York State Energy Research and Development Authority (NYSERDA) offers objective information and analysis, innovative programs, technical expertise, and support to help New Yorkers increase energy efficiency, save money, use renewable energy, and accelerate economic growth. reduce reliance on fossil fuels. To learn more about NYSERDA’s programs, visit nyserda.ny.gov or follow us on X, Facebook, YouTube, or Instagram.

The BuildingsBench datasets consist of: Buildings-900K: A large-scale dataset of 900K buildings for pretraining models on the task of short-term load forecasting (STLF). Buildings-900K is statistically representative of the entire U.S. building stock. 7 real residential and commercial building datasets for benchmarking two downstream tasks evaluating generalization: zero-shot STLF and transfer learning for STLF. Buildings-900K can be used for pretraining models on day-ahead STLF for residential and commercial buildings. The specific gap it fills is the lack of large-scale and diverse time series datasets of sufficient size for studying pretraining and finetuning with scalable machine learning models. Buildings-900K consists of synthetically generated energy consumption time series. It is derived from the NREL End-Use Load Profiles (EULP) dataset (see link to this database in the links further below). However, the EULP was not originally developed for the purpose of STLF. Rather, it was developed to "...help electric utilities, grid operators, manufacturers, government entities, and research organizations make critical decisions about prioritizing research and development, utility resource and distribution system planning, and state and local energy planning and regulation." Similar to the EULP, Buildings-900K is a collection of Parquet files and it follows nearly the same Parquet dataset organization as the EULP. As it only contains a single energy consumption time series per building, it is much smaller (~110 GB). BuildingsBench also provides an evaluation benchmark that is a collection of various open source residential and commercial real building energy consumption datasets. The evaluation datasets, which are provided alongside Buildings-900K below, are collections of CSV files which contain annual energy consumption. The size of the evaluation datasets altogether is less than 1GB, and they are listed out below: ElectricityLoadDiagrams20112014 Building Data Genome Project-2 Individual household electric power consumption (Sceaux) Borealis SMART IDEAL Low Carbon London A README file providing details about how the data is stored and describing the organization of the datasets can be found within each data lake version under BuildingsBench.

Monthly consumption and cost data by borough and development. Data set includes utility vendor and meter information.

This is the first data release from the Public Utility Data Liberation (PUDL) project. It can be referenced & cited using https://doi.org/10.5281/zenodo.3653159

For more information about the free and open source software used to generate this data release, see Catalyst Cooperative's PUDL repository on Github, and the associated documentation on Read The Docs. This data release was generated using v0.3.1 of the catalystcoop.pudl python package.

Included Data Packages

This release consists of three tabular data packages, conforming to the standards published by Frictionless Data and the Open Knowledge Foundation. The data are stored in CSV files (some of which are compressed using gzip), and the associated metadata is stored as JSON. These tabular data can be used to populate a relational database.

• pudl-eia860-eia923:
  Data originally collected and published by the US Energy Information Administration (US EIA). The data from EIA Form 860 covers the years 2011-2018. The Form 923 data covers 2009-2018. A large majority of the data published in the original data sources has been included, but some parts, like fuel stocks on hand, and EIA 923 schedules 6, 7, & 8 have not yet been integrated.
• pudl-eia860-eia923-epacems:
  This data package contains all of the same data as the pudl-eia860-eia923 package above, as well as the Hourly Emissions data from the US Environmental Protection Agency's (EPA's) Continuous Emissions Monitoring System (CEMS) from 1995-2018. The EPA CEMS data covers thousands of power plants at hourly resolution for decades, and contains close to a billion records.
• pudl-ferc1:
  Seven data tables from FERC Form 1 are included, primarily relating to individual power plants, and covering the years 1994-2018 (the entire span of time for which FERC provides this data). These tables are the only ones which have been subjected to any cleaning or organization for programmatic use within PUDL. The complete, raw FERC Form 1 database contains 116 different tables with many thousands of columns of mostly financial data. We will archive a complete copy of the multi-year FERC Form 1 Database as a file-based SQLite database at Zenodo, independent of this data release. It can also be re-generated using the catalystcoop.pudl Python package and the original source data files archived as part of this data release.

Contact Us

If you're using PUDL, we would love to hear from you! Even if it's just a note to let us know that you exist, and how you're using the software or data. You can also:

• Subscribe to our announcements list for email updates.
• Use the Github issue tracker to file bugs, suggest improvements, or ask for help.
• Email the project team at pudl@catalyst.coop for private communications.
• Follow @CatalystCoop on Twitter.

Using the Data

The data packages are just CSVs (data) and JSON (metadata) files. They can be used with a variety of tools on many platforms. However, the data is organized primarily with the idea that it will be loaded into a relational database, and the PUDL Python package that was used to generate this data release can facilitate that process. Once the data is loaded into a database, you can access that DB however you like.

Make sure conda is installed

None of these commands will work without the conda Python package manager installed, either via Anaconda or miniconda:

• Install Anaconda
• Install miniconda

Download the data

First download the files from the Zenodo archive into a new empty directory. A couple of them are very large (5-10 GB), and depending on what you're trying to do you may not need them.

• If you don't want to recreate the data release from scratch by re-running the entire ETL process yourself, and you don't want to create a full clone of the original FERC Form 1 database, including all of the data that has not yet been integrated into PUDL, then you don't need to download pudl-input-data.tgz.
• If you don't need the EPA CEMS Hourly Emissions data, you do not need to download pudl-eia860-eia923-epacems.tgz.

Load All of PUDL in a Single Line

Use cd to get into your new directory at the terminal (in Linux or Mac OS), or open up an Anaconda terminal in that directory if you're on Windows.

If you have downloaded all of the files from the archive, and you want it all to be accessible locally, you can run a single shell script, called load-pudl.sh:

bash pudl-load.sh

This will do the following:

• Load the FERC Form 1, EIA Form 860, and EIA Form 923 data packages into an SQLite database which can be found at sqlite/pudl.sqlite.
• Convert the EPA CEMS data package into an Apache Parquet dataset which can be found at parquet/epacems.
• Clone all of the FERC Form 1 annual databases into a single SQLite database which can be found at sqlite/ferc1.sqlite.

Selectively Load PUDL Data

If you don't want to download and load all of the PUDL data, you can load each of the above datasets separately.

Create the PUDL conda Environment

This installs the PUDL software locally, and a couple of other useful packages:

conda create --yes --name pudl --channel conda-forge \
  --strict-channel-priority \
  python=3.7 catalystcoop.pudl=0.3.1 dask jupyter jupyterlab seaborn pip
conda activate pudl

Create a PUDL data management workspace

Use the PUDL setup script to create a new data management environment inside this directory. After you run this command you'll see some other directories show up, like parquet, sqlite, data etc.

pudl_setup ./

Extract and load the FERC Form 1 and EIA 860/923 data

If you just want the FERC Form 1 and EIA 860/923 data that has been integrated into PUDL, you only need to download pudl-ferc1.tgz and pudl-eia860-eia923.tgz. Then extract them in the same directory where you ran pudl_setup:

tar -xzf pudl-ferc1.tgz
tar -xzf pudl-eia860-eia923.tgz

To make use of the FERC Form 1 and EIA 860/923 data, you'll probably want to load them into a local database. The datapkg_to_sqlite script that comes with PUDL will do that for you:

datapkg_to_sqlite \
  datapkg/pudl-data-release/pudl-ferc1/datapackage.json \
  datapkg/pudl-data-release/pudl-eia860-eia923/datapackage.json \
  -o datapkg/pudl-data-release/pudl-merged/

Now you should be able to connect to the database (~300 MB) which is stored in sqlite/pudl.sqlite.

Extract EPA CEMS and convert to Apache Parquet

If you want to work with the EPA CEMS data, which is much larger, we recommend converting it to an Apache Parquet dataset with the included epacems_to_parquet script. Then you can read those files into dataframes directly. In Python you can use the pandas.DataFrame.read_parquet() method. If you need to work with more data than can fit in memory at one time, we recommend using Dask dataframes. Converting the entire dataset from datapackages into Apache Parquet may take an hour or more:

tar -xzf pudl-eia860-eia923-epacems.tgz
epacems_to_parquet datapkg/pudl-data-release/pudl-eia860-eia923-epacems/datapackage.json

You should find the Parquet dataset (~5 GB) under parquet/epacems, partitioned by year and state for easier querying.

Clone the raw FERC Form 1 Databases

If you want to access the entire set of original, raw FERC Form 1 data (of which only a small subset has been cleaned and integrated into PUDL) you can extract the original input data that's part of the Zenodo archive and run the ferc1_to_sqlite script using the same settings file that was used to generate the data release:

tar -xzf pudl-input-data.tgz
ferc1_to_sqlite data-release-settings.yml

You'll find the FERC Form 1 database (~820 MB) in sqlite/ferc1.sqlite.

Data Quality Control

We have performed basic sanity checks on much but not all of the data compiled in PUDL to ensure that we identify any major issues we might have introduced through our processing

This dataset, compiled by NREL using data from ABB, the Velocity Suite and the U.S. Energy Information Administration dataset 861, provides average residential, commercial and industrial electricity rates with likely zip codes for both investor owned utilities (IOU) and non-investor owned utilities. Note: the files include average rates for each utility (not average rates per zip code), but not the detailed rate structure data found in the OpenEI U.S. Utility Rate Database.

Over the past half a century, the world's electricity consumption has continuously grown, reaching approximately 27,000 terawatt-hours by 2023. Between 1980 and 2023, electricity consumption more than tripled, while the global population reached eight billion people. Growth in industrialization and electricity access across the globe have further boosted electricity demand. China's economic rise and growth in global power use Since 2000, China's GDP has recorded an astonishing 15-fold increase, turning it into the second-largest global economy, behind only the United States. To fuel the development of its billion-strong population and various manufacturing industries, China requires more energy than any other country. As a result, it has become the largest electricity consumer in the world. Electricity consumption per capita In terms of per capita electricity consumption, China and other BRIC countries are still vastly outpaced by developed economies with smaller population sizes. Iceland, with a population of less than half a million inhabitants, consumes by far the most electricity per person in the world. Norway, Qatar, Canada, and the United States also have among the highest consumption rates. Multiple contributing factors such as the existence of power-intensive industries, household sizes, living situations, appliance and efficiency standards, and access to alternative heating fuels determine the amount of electricity the average person requires in each country.

About this dataset

Context

The dataset tabulates the Energy population distribution across 18 age groups. It lists the population in each age group along with the percentage population relative of the total population for Energy. The dataset can be utilized to understand the population distribution of Energy by age. For example, using this dataset, we can identify the largest age group in Energy.

Key observations

The largest age group in Energy, IL was for the group of age 70 to 74 years years with a population of 140 (11.96%), according to the ACS 2019-2023 5-Year Estimates. At the same time, the smallest age group in Energy, IL was the 25 to 29 years years with a population of 35 (2.99%). Source: U.S. Census Bureau American Community Survey (ACS) 2019-2023 5-Year Estimates

Content

When available, the data consists of estimates from the U.S. Census Bureau American Community Survey (ACS) 2019-2023 5-Year Estimates

Age groups:

• Under 5 years
• 5 to 9 years
• 10 to 14 years
• 15 to 19 years
• 20 to 24 years
• 25 to 29 years
• 30 to 34 years
• 35 to 39 years
• 40 to 44 years
• 45 to 49 years
• 50 to 54 years
• 55 to 59 years
• 60 to 64 years
• 65 to 69 years
• 70 to 74 years
• 75 to 79 years
• 80 to 84 years
• 85 years and over

Variables / Data Columns

• Age Group: This column displays the age group in consideration
• Population: The population for the specific age group in the Energy is shown in this column.
• % of Total Population: This column displays the population of each age group as a proportion of Energy total population. Please note that the sum of all percentages may not equal one due to rounding of values.

Good to know

Margin of Error

Data in the dataset are based on the estimates and are subject to sampling variability and thus a margin of error. Neilsberg Research recommends using caution when presening these estimates in your research.

Custom data

If you do need custom data for any of your research project, report or presentation, you can contact our research staff at research@neilsberg.com for a feasibility of a custom tabulation on a fee-for-service basis.

Inspiration

Neilsberg Research Team curates, analyze and publishes demographics and economic data from a variety of public and proprietary sources, each of which often includes multiple surveys and programs. The large majority of Neilsberg Research aggregated datasets and insights is made available for free download at https://www.neilsberg.com/research/.

Recommended for further research

This dataset is a part of the main dataset for Energy Population by Age. You can refer the same here

U.S. Electric Power Transmission LinesThis feature layer, utilizing data from Homeland Infrastructure Foundation-Level Data (HIFLD), depicts electric power transmission lines in the United States. Per HIFLD, "Transmission Lines are the system of structures, wires, insulators and associated hardware that carry electric energy from one point to another in an electric power system. Lines are operated at relatively high voltages varying from 69 kV up to 765 kV, and are capable of transmitting large quantities of electricity over long distances. Underground transmission lines are included where sources were available."138 Kilovolt Transmission LineData downloaded: 5/16/2025Data source: Transmission LinesData modification: noneFor more information: Electricity ExplainedSupport documentation: Transmission LinesFor feedback, please contact: ArcGIScomNationalMaps@esri.comThe Homeland Infrastructure Foundation-Level DataPer HIFLD, "The Homeland Infrastructure Foundation-Level Data (HIFLD) Subcommittee was established…to address improvements in collection, processing, sharing, and protection of homeland infrastructure geospatial information across multiple levels of government, and to develop a common foundation of homeland infrastructure data to be used for visualization and analysis on all classification domains."

A comprehensive dataset of average residential, commercial, and combined electricity rates in cents per kWh for all 50 U.S. states.