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applications biomass bioreactor landfill biorefinery building capture carbon sequestration Change Technology Program chemical Climate Change Technology coal combustion Commercialization and Deployment components conversion cost crop Current Research cycle Demonstration RD&D Goals Deployment Activities distributed electricity energy efficiency energy storage engine enhanced environmental equipment ethanol feedstock fuel cell greenhouse gas grid heat high GWP gases high-temperature hybrid hydrogen production implemented improved increase industry infrastructure injection integrated landfill gas Long Term manufacturing Market Context materials measurement membrane methane microturbines models monitoring natural gas near-term needed nitrogen nuclear operation optimize oxide perfluorocarbon performance potential power electronics power plants Precision agriculture processes projects RD&D Activities RD&D Challenges reactors Recent Progress Representative Technologies selective catalytic reduction sensors soil carbon solar syngas System Concepts Technology Description Technology Options Technology Status/Applications temperature testing thermal transmission transportation U.S. Climate Change United utilization vehicles waste
82 ページ - CGCS shall meet the requirements of the American Society of Mechanical Engineers (ASME) Boiler and Pressure Vessel Code, Section III, nuclear power plant components (with minor exceptions) and certain specified Reactor Development and Technology (RDT) standards.
61 ページ - This project will be undertaken with international partners to dramatically reduce air pollution and capture and store emissions of greenhouse gases.
114 ページ - Forum, a group of ten leading nuclear nations (United Kingdom, Argentina, Brazil, Canada, France, Japan, Republic of Korea, Republic of South Africa, Switzerland, and the United States), who last year selected six promising technologies for joint research, development, and demonstration. While the Department has not yet decided upon which of these technologies it will eventually focus, all of the technologies are of considerable interest. The six innovative...
49 ページ - Glass activity is to develop advanced glass technologies that will reduce the gap between actual melting energy use (more than 1 1 million Btu to melt a ton of glass as measured in 19%) and the theoretical minimum (2.5 million Btu per ton) by 50 percent by 2020.
2 ページ - ... for 18 seconds, and 30kW continuous at a system cost of $12/kW peak. • 60% peak energy-efficient, durable fuel cell power system (including hydrogen storage) that achieves a 325 W/kg power density and 220 W/L operating on hydrogen. Cost targets are at $45/kW by 2010 ($30/kW by 2015).2 • To enable clean, energy-efficient vehicles operating on clean, hydrocarbon-based fuels powered by either internal-combustion powertrains or fuel cells, the goals are: • Internal combustion engine powertrain...
14 ページ - Agreement between the Federal Aviation Administration (FAA) and the National Aeronautics and Space Administration (NASA).
28 ページ - The team then initiated additional sets of elimination parametrics and conservation strategies until no more energy-conserving strategies could be identified. LEED SYSTEM The team used the US Green Building Council's LEED (Leadership in Energy and Environmental Design) Green Building Rating System as a design guidance and decision-making tool. Because the project currently is out to...
156 ページ - Fuel cells generate electricity through an electrochemical process in which the energy stored in a fuel is converted directly into DC electricity and thermal energy.