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Green Power Equivalency Calculator Methodologies


Kilowatt-hour conversion

The Green Power Equivalency Calculator uses eGRID (Emissions & Generation Resource Integrated Information Database) non-baseload carbon dioxide (CO2) output emission rates when converting kilowatt-hours (kWh) into avoided units of CO2 emissions. Depending on user data input, the calculator uses either the eGRID subregion non-baseload emission rates the U.S. non-baseload emission rate for this calculation.

Calculation

Note: Please refer to the eGRID Web site for individual nonbaseload subregion emissions rates.

7.18 x 10-4 metric tons CO2 / kWh (eGRID2007 Version 1.1, U.S. annual non-baseload CO2 output emission rate, year 2005 data)

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Passenger vehicles per year

Passenger vehicles are defined as 2-axle 4-tire vehicles, including passenger cars, vans, pickup trucks, and sport/utility vehicles.

In 2005, the weighted average combined fuel economy of cars and light trucks combined was 19.7 miles per gallon (FHWA 2006). The average vehicle miles traveled in 2005 was 11,856 miles per year.

In 2005, the ratio of carbon dioxide emissions to total emissions (including carbon dioxide, methane, and nitrous oxide, all expressed as carbon dioxide equivalents) for passenger vehicles was 0.971 (EPA 2007).

The amount of carbon dioxide emitted per gallon of motor gasoline burned is 8.81*10-3 metric tons, as calculated in the "Gallons of gasoline consumed" section.

To determine annual GHG emissions per passenger vehicle, the following methodology was used: vehicle miles traveled (VMT) was divided by average gas mileage to determine gallons of gasoline consumed per vehicle per year. Gallons of gasoline consumed was multiplied by carbon dioxide per gallon of gasoline to determine carbon dioxide emitted per vehicle per year. Carbon dioxide emissions were then divided by the ratio of carbon dioxide emissions to total vehicle greenhouse gas emissions to account for vehicle methane and nitrous oxide emissions.

Calculation

Note: Due to rounding, performing the calculations given in the equations below may not return the exact results shown.

8.81*10-3 metric tons CO2/gallon gasoline * 11,856 VMT car/truck average * 1/19.7 miles per gallon car/truck average * 1 CO2, CH4, and N2O/0.971 CO2 = 5.46 metric tons CO2E /vehicle/year

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Gallons of gasoline consumed

Average heat content of conventional motor gasoline is 5.22 million btu per barrel (EPA 2007). Average carbon coefficient of motor gasoline is 19.33 kg carbon per million btu (EPA 2007). Fraction oxidized to CO2 is 100 percent (IPCC 2006).

Carbon dioxide emissions per barrel of gasoline were determined by multiplying heat content times the carbon coefficient time the fraction oxidized times the ratio of the molecular weight ratio of carbon dioxide to carbon (44/12). A barrel equals 42 gallons.

Calculation

Note: Due to rounding, performing the calculations given in the equations below may not return the exact results shown.

5.22 mmbtu/barrel * 19.33 kg C/mmbtu * 1 barrel/42 gallons * 44 g CO2/12 g C * 1 metric ton/1000 kg = 8.81*10-3 metric tons CO2/gallon

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Barrels of oil consumed

Average heat content of crude oil is 5.80 million btu per barrel (EPA 2007). Average carbon coefficient of crude oil is 20.33 kg carbon per million btu (EPA 2007). Fraction oxidized is 100 percent (IPCC 2006).

Carbon dioxide emissions per barrel of crude oil were determined by multiplying heat content times the carbon coefficient times the fraction oxidized times the ratio of the molecular weight of carbon dioxide to that of carbon (44/12).

Calculation

Note: Due to rounding, performing the calculations given in the equations below may not return the exact results shown.

5.80 mmbtu/barrel * 20.33 kg C/mmbtu * 44 g CO2/12 g C * 1 metric ton/1000 kg = 0.43 metric tons CO2/barrel

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Propane cylinders used for home barbeques

Average heat content of liquefied petroleum gas is 21,591 btu per pound (EPA 2007). Average carbon coefficient of liquefied petroleum gases is 16.99 kg carbon per million btu (EPA 2007). Fraction oxidized is 100 percent (IPCC 2006).

Carbon dioxide emissions per pound of propane were determined by multiplying heat content times the carbon coefficient times the fraction oxidized times the ratio of the molecular weight of carbon dioxide to that of carbon (44/12). Propane cylinders vary with respect to size - for the purpose of this equivalency calculation, a typical cylinder for home use was assumed to contain 18 pounds of propane.

Calculation

Note: Due to rounding, performing the calculations given in the equations below may not return the exact results shown.

21,591 btu/pound * 1 mmbtu/106 btu * 16.99 kg C/mmbtu * 44 g CO2/12 g C * 18 pounds/1 canister * 1 metric ton/1000 kg = 0.024 metric tons CO2/canister

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Railcars of coal burned

Average heat content of coal in 2005 was 22.68 million btu per metric ton (EPA 2007). Average carbon coefficient of coal in 2005 was 25.34 kilograms carbon per million btu (EPA 2007). Fraction oxidized is 100 percent (IPCC 2006).

Carbon dioxide emissions per ton of coal were determined by multiplying heat content times the carbon coefficient times the fraction oxidized times the ratio of the molecular weight of carbon dioxide to that of carbon (44/12). The amount of coal in an average railcar was assumed to be 100.19 short tons, or 90.89 metric tons (Hancock 2001).

Calculation

Note: Due to rounding, performing the calculations given in the equations below may not return the exact results shown.

22.68 mmbtu/metric ton coal * 25.34 kg C/mmbtu * 44g CO2/12g C * 90.89 metric tons coal/railcar * 1 metric ton/1000 kg = 191.5 metric tons CO2/railcar

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Coal fired power plant for one year

In 2005 there were 2,134,520,641 tons of CO2 emitted from power plants whose primary source of fuel was coal (CAMD, 2005).

In 2005 there were a total of 417 power plants whose primary source of fuel was coal (CAMD, 2005).

Carbon dioxide emissions per power plant were calculated by dividing the number of power plants by the total emissions from power plants whose primary source of fuel was coal. The quotient was then converted from tons to metric tons.

Calculation

Note: Due to rounding, performing the calculations given in the equations below may not return the exact results shown.

2,134,520,641 tons of CO2 * 1/417power plants * 0.9072 metric tons / 1 short ton = 4,643,734 metric tons CO2/power plant

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Home electricity use

In 2001, there were 107 million homes in the United States; of those, 73.7 million were single-family homes* (EIA, 2003). On average, each single-family home consumed 11,965 kWh of delivered electricity (EIA 2003). The national average carbon dioxide (CO2) output rate for electricity in 2005 was 1,329 lbs CO2 per megawatt-hour (EPA 2009).

Annual single-family home electricity consumption was multiplied by the carbon dioxide emission rate (per unit of electricity delivered) to determine annual carbon dioxide emissions per home.

Calculation

Note: Due to rounding, performing the calculations given in the equations below may not return the exact results shown.

11,965 kWh per home * 1,329.35 lbs CO2 per megawatt-hour delivered * 1 mWh/1000 kWh * 1 metric ton/2204.6 lb = 7.21 metric tons CO2/home.

Sources

*A single-family home is defined in the U.S. Department of Energy’s Residential Energy Consumption Survey as follows: A housing unit, detached or attached, that provides living space for one home or family. Attached houses are considered single-family houses as long as they are not divided into more than one housing unit and they have independent outside entrance. A single-family house is contained within walls extending from the basement (or the ground floor, if there is no basement) to the roof. A mobile home with one or more rooms added is classified as a single-family home. Townhouses, rowhouses, and duplexes are considered single-family attached housing units, as long as there is no home living above another one within the walls extending from the basement to the roof to separate the units.

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