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Electrical Energy01:10

Electrical Energy

1.6K
Using electric appliances for a longer period of time consumes more electrical energy and results in a higher electric bill. The energy produced by the transfer of electrons from one point to another is known as electrical energy. If power is delivered at a constant rate, the electrical energy can be defined as the product of power used by the device for a period of time. The energy unit on electric bills is the kilowatt-hour, where one kilowatt-hour is equivalent to 3.6 × 106 joules.
1.6K
Electrical Power01:07

Electrical Power

3.6K
Electric power is the product of current and voltage, represented in units of joules per second, or watts. For example, cars often have one or more auxiliary power outlets with which you can charge a cell phone or other electronic devices. These outlets may be rated at 20 amps and 12 volts, so that the circuit can deliver a maximum power of 240 watts. Consider a 25 Watt bulb and a 60 Watt bulb. The conversion of electrical energy produces heat and light, while the kinetic energy lost by the...
3.6K
Energy Losses in Transformers01:21

Energy Losses in Transformers

1.2K
In an ideal transformer, it is assumed that there are no energy losses, and, hence, all the power at the primary winding is transferred to the secondary winding. However, in reality,  the transformers always have some energy losses, and, hence, the output power obtained at the secondary winding is less than the input power at the primary winding due to energy losses.
There are four main reasons for energy losses in transformers.
The first cause can be  the high resistance of the...
1.2K
Energy Diagrams - I01:14

Energy Diagrams - I

5.5K
The dynamics of a mechanical system can be easily understood by interpreting a potential energy diagram. Since energy is a scalar quantity, the interpretation of the dynamics of the system becomes even simpler.
Take the example of a skater on a parabolic ramp. The potential energy at different points along the ramp will be proportional to the height of the ramp, which varies quadratically with the horizontal position on the ramp. As the skater moves down the ramp from the highest position,...
5.5K
Power System Distribution01:25

Power System Distribution

990
Power system distribution involves delivering electrical energy from power plants to consumers through a network of transmission and distribution systems. The process begins at power plants, where energy from coal, gas, nuclear, water, and wind is converted into electrical energy. These plants use three-phase generators, typically rated between 50 to 1300 MVA, with terminal voltages ranging from a few kV to 20 kV, depending on the size and age of the units.
The transmission system is designed...
990
Load-frequency control01:28

Load-frequency control

570
Load-frequency control (LFC) is vital for maintaining power system stability, ensuring that frequency and power flows remain within acceptable limits during load changes. Turbine-governor control eliminates rotor accelerations and decelerations following load changes. However, a steady-state frequency error persists when the change in the turbine-governor reference setting is zero. In an interconnected power system, each area agrees to export or import a scheduled amount of power through...
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Related Experiment Video

Updated: Jan 2, 2026

Design and Use of a Full Flow Sampling System FFS for the Quantification of Methane Emissions
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Design and Use of a Full Flow Sampling System FFS for the Quantification of Methane Emissions

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Tracking emissions in the US electricity system.

Jacques A de Chalendar1, John Taggart2, Sally M Benson3

  • 1Energy Resources Engineering, Stanford University, Stanford, CA 94305-2205; jdechalendar@stanford.edu.

Proceedings of the National Academy of Sciences of the United States of America
|December 4, 2019
PubMed
Summary
This summary is machine-generated.

Tracking pollution embodied in electricity production and consumption is crucial for reducing emissions. This study quantifies these emissions across US Balancing Authorities, revealing the impact of electricity exchanges and regional disparities.

Keywords:
carbon intensity of electricityelectricity system emissions factorsemissions embodied in electricity exchangesrenewable energy policy

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Area of Science:

  • Environmental Science
  • Energy Systems Analysis
  • Economics

Background:

  • Understanding electricity consumption and production is vital for mitigating emissions and their health/climate impacts.
  • Existing methods often lack the granularity to fully capture emissions embodied in electricity trade.

Purpose of the Study:

  • To adapt an economic input-output model for tracking emissions through electric grids.
  • To quantify pollution embodied in electricity production, exchanges, and consumption for 66 continental US Balancing Authorities (BAs).
  • To provide a high-resolution dataset for evaluating emissions footprints.

Main Methods:

  • Utilized an economic input-output model adapted for emissions flow analysis.
  • Integrated multiple publicly available datasets for the year 2016.
  • Generated hourly and BA-level data for emissions tracking.

Main Results:

  • Demonstrated the significance of location, temporal factors, and electricity exchanges in emissions footprint estimation.
  • Highlighted that importing electricity can conflict with climate goals.
  • Revealed that regions exporting high-emission electricity disproportionately burden citizens with air pollution.

Conclusions:

  • Greater resolution in electric-sector emissions indices is necessary for effective policy design and evaluation.
  • Electricity trade patterns significantly influence regional emissions burdens and climate goals.
  • The study provides a valuable dataset for policymakers, regulators, and large consumers.