A Life Cycle Assessment and Economic Analysis of Wind Turbines Using Monte Carlo Simulation

Abstract

The United States depends heavily on nonrenewable fossil fuels to generate electricity, Using renewable energy sources, such as wind, could reduce air emissions and fossil fuel dependency. Previous studies have examined the life cycle costs and environmental impacts of using wind to generate electricity, but results have varied due to inconsistent modeling assumptions. This research uses Monte Carlo simulation to conduct an economic payback analysis and life cycle assessment of 11 modern, utility-scale wind turbines. Hourly meteorological data was used to evaluate 239 U,S, locations, For each location, the wind turbine with the shortest median payback period was assumed to be the economically preferred turbine model. This simulation demonstrates that variance in the model output is primarily caused by differences in location-specific climate data (wind speed, air density), Depending on the location, the median economic payback periods ranged from 2 to 132 years, 41% of the locations had median payback periods less than 10 years, and 63% less than 15 years, Considering a typical turbine lifespan of 15-30 years, wind turbines are not economically viable at all locations, At locations with favorable wind resources, wind turbines are likely to be superior to electricity production using natural gas or coal, For the preferred wind turbine, the median life cycle energy intensities at all 239 locations ranged from 0,05-0,54 (KWh energy inputs/KWh outputs), compared to 2,3 for natural gas and 2,6-3,5 for coal-fired electricity generation, The median CO2 (eq) intensity values range from 13-156 g-CO2 (eq)/kWh for the preferred wind turbine, compared to 585 g-CO2 (eq)/kWh for natural gas and 757-1042 g-CO2 (eq)/kWh for coal-fired power plants, SOx and NOx intensity values range from 0.04-0.50 g-SOx/kWh and 0.05-0.66 g-NOx/kWh for the preferred wind turbine.

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Document Details

Document Type
Technical Report
Publication Date
Mar 01, 2003
Accession Number
ADA415268

Entities

People

  • Edward J. Liberman

Organizations

  • Air Force Institute of Technology

Tags

DTIC Thesaurus Topics

  • Chemistry
  • Climate Change
  • Composite Materials
  • Dielectric Gases
  • Economic Analysis
  • Electric Power Production
  • Environment
  • Fossil Fuels
  • Glass Fibers
  • Materials Laboratories
  • Materials Processing
  • Materials Science
  • Materials Testing
  • Nitrogen Oxides
  • Renewable Energy
  • Wind Energy
  • Wind Turbines

Fields of Study

  • Environmental science

Readers

  • Energy Conservation and Renewable Energy Engineering.
  • Internal Combustion Engine (ICE) Technology.
  • Mathematics or Statistics