Selecting the fuel and heating system best suited for your needs depends on many factors. These include: the cost and availability of the fuel or energy source; the type of appliance used to convert that fuel to heat and how the heat is distributed in your house; the cost to purchase, install, and maintain the heating appliance; the heating appliance's and heat delivery system's efficiency; and the environmental impacts associated with the heating fuel.
One somewhat simple way to evaluate heating options is to compare the cost of the fuel. To do that, you have to know the energy content of the fuel and the efficiency by which it is converted to useful heat.
Fuels are measured in physical units, such as gallons of oil or propane, cubic feet of natural gas, or kilowatt?hours or electricity (kWh). They are also measured by heat content. In the United States, the most commonly used value for expressing the energy value or heat content of a fuel is the British thermal unit (Btu). One Btu is the amount of energy needed to raise the temperature of one pound of water one degree Fahrenheit (F), when water is at about 39 degrees F. One "therm" is 100,000 Btu. For a more detailed explanation of heating values, see the discussion at the end of this fact sheet.
Btu Content of Fuels
Since the actual heat content of different types of fuels varies, the approximate average values are often used. The table below provides a list of typical heating fuels and the Btu content in the units that they are typically sold in the United States. The figures below are general references for residential heating applications only. Commercial and industrial users should obtain more precise values from their fuel vendors.
Table 1: Average Btu Content of Fuels Fuel Type No. of Btu/Unit Fuel Oil (No. 2) 140,000/gallon Electricity 3,412/kWh Natural Gas 1,025,000/thousand cubic feet Propane 91,330/gallon Wood (air dried)* 20,000,000/cord or 8,000/pound Pellets (for pellet stoves; premium) 16,500,000/ton Kerosene 135,000/gallon Coal 28,000,000/ton
*See the discussion on wood heating values below.
These standards of measurement make comparisons of fuel types possible. For example:
* The heat content of one gallon of fuel oil roughly equals that of 41 kWh of electricity, 137 cubic feet of natural gas, 1.5 gallons of propane, 17.5 pounds of air-dried wood, 17 pounds of pellets, a gallon of kerosene, or 10 pounds of coal.
* One million Btu is the heat equivalent of approximately 7 gallons of No. 2 heating oil or kerosene, 293 kWh of electricity, 976 cubic feet of natural gas, 11 gallons of propane, 125 pounds of air-dried wood, 121 pounds of pellets, or 71 pounds of coal.
* The efficiency of the heating appliance is an important factor when determining the cost of a given amount of heat. In general, the efficiency is determined by measuring how well an appliance turns fuel into useful heat. (The condition of the heat distribution or delivery system also affects the overall system efficiency.) Many types of space heating appliances must meet minimum standards for efficiency developed by the U.S. Department of Energy. Table 2 provides average efficiencies for common heating appliances.
Table 2: Estimated Average Fuel Conversion Efficiency of Common Heating Appliances Fuel Type - Heating Equipment Efficiency (%) Coal (bituminous) Central heating, hand-fired 45.0 Central heating, stoker-fired 60.0 Water heating, pot stove (50 gal.) 14.5 Oil High efficiency central heating 89.0 Typical central heating 80.0 Water heater (50 gal.) 59.5 Gas High efficiency central furnace 97.0 Typical central boiler 85.0 Minimum efficiency central furnace 78.0 Room heater, unvented 99.0 Room heater, vented 65.0 Water heater (50 gal.) 62.0 Electricity Baseboard, resistance 99.0 Central heating, forced air 97.0 Central heating, heat pump 200+ Ground source heat pump 300+ Water heaters (50 gal.) 97.0 Wood & Pellets Franklin stoves 30.0 - 40.0 Stoves with circulating fans 40.0 - 70.0 Catalytic stoves 65.0 - 75.0 Pellet stoves 85.0 - 90.0 Comparing Fuel Costs
You can use the following method to estimate the costs of producing one million Btu of heat using different heating appliances and fuels. To do this, you need to know the efficiency of the appliance and the unit price of the fuel. To get the unit price of the fuel, take your energy bill for one month and divide it by the number of units you consumed or purchased during the billing period. This will include all the costs associated with buying that type of fuel, such as the cost of the fuel itself and other charges such as transmission, distribution or delivery, and taxes. You can also contact the utility or fuel supplier in your area for the unit price of the fuel and the cost to deliver it to your house. Remember, the fuel price should not be the sole measure for selecting a heating appliance.
To use the formula below, remember to use a decimal for the appliance heating efficiency you are assuming (see Table 2). You must first convert the Btu content of the fuel per unit to millions of Btu by dividing the fuel's Btu content per unit by 1,000,000. For example: 3,413 Btu/kWh (electricity) divided by 1,000,000 = 0.003413.
* Energy cost ($ per million Btu) = Cost per unit of fuel ÷ [ Fuel energy content (in millions Btu per unit) × Heating system efficiency (in decimal).]
Examples: Note: the fuel costs used below are the national annual average residential fuel prices in 2001 according to the Energy Information Administration (EIA), U.S. Department of Energy. Prices will vary by location and season. Also, it is difficult to predict future costs for fuels. The system efficiencies used below are for these examples only.
* Electric resistance baseboard heat cost = $0.086 (price per kWh) ÷ [ 0.003412 × 0.99 (efficiency)] = $25.46 per million Btu. * Electric heat pump heat cost = $0.086 (price per kWh) ÷ [ 0.003412 × 2 (efficiency)] = $12.60 per million Btu. * Natural gas (in medium efficiency central heating system) heat cost = $9.96 (per thousand cubic feet) ÷ [ 1.03 × 0.90 (efficiency) ] = $10.74 per million Btu. * Oil (in medium efficiency central heating system) heat cost = $1.25 (price per gallon) ÷ [ 0.14 × 0.85 (efficiency) ] = $10.5 per million Btu. * Propane (in medium efficiency central heating system) heat cost = $1.09 (price per gallon) ÷ [ 0.0913 × 0.85 (efficiency) ] = $14.05 per million Btu.
Heating Values - A More Detailed Discussion
The heating values provided in the Table 1 above are the "higher" or "gross" heating values of the fuels as estimated by the Energy Information Administration in the Annual Energy Review 2001, and other sources. Higher (or gross) heating values are commonly used in energy calculations in the United States. "Net" or "lower" heating values may also be used. The difference between the two values is the amount of energy that is necessary to vaporize water that is contained in the fuel or created in the combustion process when hydrogen in the fuel is combined with oxygen to form water vapor. In general, this difference can range from as little as 2 percent to as much as 60 percent, depending on the hydrogen or moisture content of specific fuels. The heat energy contained in the water vapor is generally lost as the combustion gases leave the appliance vent or chimney. Some types of combustion appliances, however, such as high efficiency "condensing" forced-air furnaces, are able to capture much of the heat contained in the water vapor before it leaves the furnace vent (thus the term "condensing"). Since electricity is not burned in a heating appliance, the two values are equal.
Wood heating values can vary significantly. The most important factor affecting useful Btu content is the moisture content of the wood. Well-seasoned, air-dried wood will typically have a moisture content of around 20 percent (when compared to a "bone dry" sample of the wood). A very rough approximation of the effect of moisture content on the heating value is for every percent increase in moisture content (relative to a bone-dry sample) there is a one percent decrease in heating value. The other factor affecting heat content is the tree species of the wood. Higher heating values of wood can vary from 8,000 to 10,000 Btu per pound, bone dry. A cord of wood is a rough measuring unit; it is a stack of wood 4 feet high, 8 feet long, and 4 feet wide. A "good" cord of wood will be tightly packed. Pellet fuels are usually made from sawdust. The Btu content will therefore vary depending on the type of wood that the sawdust is from. Pellet fuels typically have a moisture content of around 10 percent.
Most of the appliance efficiencies given in the Table 2 above roughly account for the net heating value fuels used in a vented appliance (ie one that has a chimney). An unvented space heater, such as a kerosene heater or a natural gas fireplace insert, delivers nearly all of the heating value of a fuel to the space in which it is located. It also puts all the products of combustion including carbon dioxide, water vapor, and small amounts of carbon monoxide, sulfur dioxide, and nitrous oxides into the room. These types of heating units generally require that a window be opened (slightly) for safe operation, which reduces their overall heating capability.
The system used to distribute heat from a heating appliance, such as pipes in a hydronic heating system or ducts in a forced-air system, can greatly affect the amount of heat actually delivered to individual rooms in a house. This is especially true of forced-air heating systems, if ducts are improperly sized and installed, if they leak, and/or if they are uninsulated where they pass through attics or crawl spaces. Also, central heating systems use fans (in forced-air systems to distribute the heated air) and pumps (in hydronic systems to distribute hot water to radiators), which require electricity to operate. This electricity consumption is an additional cost for heating in these types of systems.