G.L. Kulcinski scite author profile

The combination of wind energy generation and energy storage can produce a source of electricity that is functionally equivalent to a baseload coal or nuclear power plant. A model was developed to assess the technical and environmental performance of baseload wind energy systems using compressed air energy storage. The analysis examined several systems that could be operated in the midwestern United States under a variety of operating conditions. The systems can produce substantially more energy than is required from fossil or other primary sources to construct and operate them. By operation at a capacity factor of 80%, each evaluated system achieves an effective primary energy efficiency of at least five times greater than the most efficient fossil combustion technology, with greenhouse gas emission rates less than 20% of the least emitting fossil technology currently available. Life-cycle emission rates of NOx and SO2 are also significantly lower than fossil-based systems.

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Energy from Inertial Fusion

Bangerter¹,

Kulcinski²

1992

101

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Fusion is potentially a safe clean source not limited by political boundaries. Magnetic and inertial fusion share this promise, but there are differences between them. An inertial fusion power plant is based on different physics and technology from a magnetic fusion power plant and therefore presents somewhat different benefits and challenges. The facilities required to demonstrate inertial fusion power are potentially much smaller. In this article we describe concepts for such a power plant, its beneficial features and a low-cost reactor test facility for developing practical fusion power.

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G.L. Kulcinski

Life cycle energy requirements and greenhouse gas emissions from large scale energy storage systems

Lunar Source of³He for Commercial Fusion Power

Summary of Apollo, A D-³He Tokamak Reactor Design

Birth to death analysis of the energy payback ratio and CO2 gas emission rates from coal, fission, wind, and DT-fusion electrical power plants

The response of polycrystalline tungsten to 30keV helium ion implantation at normal incidence and high temperatures

Helium and deuterium implantation in tungsten at elevated temperatures

Emissions and Energy Efficiency Assessment of Baseload Wind Energy Systems

Energy from Inertial Fusion

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Resources

About

G.L. Kulcinski

Life cycle energy requirements and greenhouse gas emissions from large scale energy storage systems

Lunar Source of3He for Commercial Fusion Power

Summary of Apollo, A D-3He Tokamak Reactor Design

Birth to death analysis of the energy payback ratio and CO2 gas emission rates from coal, fission, wind, and DT-fusion electrical power plants

The response of polycrystalline tungsten to 30keV helium ion implantation at normal incidence and high temperatures

Helium and deuterium implantation in tungsten at elevated temperatures

Emissions and Energy Efficiency Assessment of Baseload Wind Energy Systems

Energy from Inertial Fusion

Contact Info

Product

Resources

About

Lunar Source of³He for Commercial Fusion Power

Summary of Apollo, A D-³He Tokamak Reactor Design