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| Determine the Cost of Compressed Air for Your Plant |
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| Written by USDOE Office of Industrial Technologies |
| Wednesday, 09 June 2010 11:09 |
Determine the Cost of Compressed Air for Your PlantMost industrial facilities need some form of compressed air, whether for running a simple air tool or for more complicated tasks such as the operation of pneumatic controls. A recent survey by the U.S. Department of Energy showed that for a typical industrial facility, approximately 10% of the electricity consumed is for generating compressed air. For some facilities, compressed air generation may account for 30% or more of the electricity consumed. Compressed air is an on-site generated utility. Very often, the cost of generation is not known; however, some companies use a value of 18-30 cents per 1,000 cubic feet of air. Compressed air is one of the most expensive sources of energy in a plant. The overall efficiency of a typical compressed air system can be as low as 10%-15%. For example, to operate a 1-horsepower (hp) air motor at 100 pounds per square inch gauge (psig), approximately 7-8 hp of electrical power is supplied to the air compressor. To calculate the cost of compressed air in your facility, use the formula shown below: Cost ($) = ((bhp) x (0.746) x (# of operating hours) x ($/kWh) x (% time) x (% full-load bhp)) / Motor Efficiency Where: bhp—Motor full-load horsepower (frequently higher than the motor nameplate horsepower—check equipment specification) 0.746—conversion between hp and kW Percent time—percentage of time running at this operating level Percent full-load bhp—bhp as percentage of full-load bhp at this operating level Motor efficiency—motor efficiency at this operating level Example A typical manufacturing facility has a 200-hp compressor (which requires 215 bhp) that operates for 6800 hours annually. It is fully loaded 85% of the time (motor efficiency = .95) and unloaded the rest of the time (25% full-load bhp and motor efficiency = .90). The aggregate electric rate is $0.05/kWh. Cost when fully loaded = ((215 bhp) x (0.746) x (6800 hrs) x ($0.05/kWh) x (0.85) x (1.0)) / .95 = $48,792 Cost when unloaded = ((215 bhp) x (0.746) x (6800 hrs) x ($0.05/kWh) x (0.15) x (0.25)) / .90 = $2,272 Annual energy cost = $48,792 + $2,272 = $51,064 Typical Lifetime Compressed Air Costs in Perspective—Costs Over 10 YearsElectricity - 76%Maintenance- 12%Equipment- 12%Assumptions in this example include a 75-hp compressor operated two shifts a day, 5 days a week at an aggregate electric rate of $0.05/kWh over 10 years of equipment life. FOR ADDITIONAL INFORMATION, PLEASE CONTACT: EERE Information Center 1-877-EERE-INF (1-877-337-3463) www.eere.energy.gov Industrial Technologies Program Energy Efficiency and Renewable Energy U.S. Department of Energy Washington, DC 20585-0121 www.eere.energy.gov/industry |
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