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- Alkali-metal_thermal_to_electric_converter abstract "The alkali-metal thermal-to-electric converter (AMTEC), originally called the sodium heat engine (SHE) was invented by Joseph T. Kummer and Neill Weber at Ford in 1966, and is described in US Patents 3404036, 3458356, 3535163 and 4049877. It is a thermally regenerative electrochemical device for the direct conversion of heat to electrical energy. It is characterized by high potential efficiencies and no moving parts except the working fluid, which make it a candidate for space power applications.This device accepts a heat input in a range 900–1300 K and produces direct current with predicted device efficiencies of 15–40%. In the AMTEC, sodium is driven around a closed thermodynamic cycle between a high-temperature heat reservoir and a cooler reservoir at the heat rejection temperature. The unique feature of the AMTEC cycle is that sodium ion conduction between a high-pressure or -activity region and a low-pressure or -activity region on either side of a highly ionically conducting refractory solid electrolyte is thermodynamically nearly equivalent to an isothermal expansion of sodium vapor between the same high and low pressures. Electrochemical oxidation of neutral sodium at the anode leads to sodium ions, which traverse the solid electrolyte, and electrons, which travel from the anode through an external circuit, where they perform electrical work, to the low-pressure cathode, where they recombine with the ions to produce low-pressure sodium gas. The sodium gas generated at the cathode then travels to a condenser at the heat-rejection temperature of perhaps 400–700 K, where liquid sodium reforms. The AMTEC thus is an electrochemical concentration cell, which converts the work generated by expansion of sodium vapor directly into electric power.The converter is based on the electrolyte used in the sodium–sulfur battery, sodium beta″-alumina, a crystalline phase of somewhat variable composition containing aluminum oxide, Al2O3, and sodium oxide, Na2O, in a nominal ratio of 5:1, and a small amount of the oxide of a small-cation metal, usually lithium or magnesium, which stabilizes the beta″ crystal structure. The sodium beta″-alumina solid electrolyte (BASE) ceramic is nearly insulating with respect to transport of electrons and is a thermodynamically stable phase in contact with both liquid sodium and sodium at low pressure.Single-cell AMTECs with open voltages as high as 1.55 V and maximum power density as high as 0.50 W/cm2 at temperature of 1173 K (900 °C) have been obtained with long-term stable refractory metal electrodes.Efficiency of AMTEC cells has reached 16% in the laboratory. High-voltage multi-tube modules are predicted to be have 20–25% efficiency, and power densities up to 0.2 kW/l appear to be achievable in the near future. Calculations show that replacing sodium with a potassium working fluid increases the peak efficiency from 28% to 31% at 1100 K with a 1 mm thick BASE tube.Most work on AMTECs has concerned sodium working fluid devices. Potassium AMTECs have been run with potassium beta″-alumina solid electrolyte ceramics and show improved power at lower operating temperatures compared to sodium AMTECs.A detailed quantitative model of the mass transport and intefacial kinetics behavior of AMTEC electrodes has been developed and used to fit and analyze the performance of a wide variety of electrodes, and to make predictions of the performance of optimized electrodes. The interfacial electrochemical kinetics can be further described quantitatively with a tunneling, diffusion, and desorption model. A reversible thermodynamic cycle for AMTEC shows that it is, at best, slightly less efficient than a Carnot cycle.AMTEC requires energy input at modest elevated temperatures and thus is easily adapted to any heat source, including radioisotope, concentrated solar, external combustion, or nuclear reactor. A solar thermal power conversion system based on an AMTEC has advantages over other technologies (including photovoltaic systems) in terms of the total power that can be achieved with such a system and the simplicity of the system (which includes the collector, energy storage (thermal storage with phase-change material) and power conversion in a compact unit). The overall system could achieve as high as 14 W/kg with present collector technology and future AMTEC conversion efficiencies. The energy storage system outperforms batteries, and the temperatures at which the system operates allows long life and reduced radiator size (heat-reject temperature of 600 K). Deep-space applications would use radioisotope thermoelectric generators; hybrid systems are in design.While space power systems are of intrinsic interest, terrestrial applications will offer large-scale applications for AMTEC systems. At the 25% efficiency projected for the device and projected costs of 350 USD/kW, AMTEC is expected to prove useful for a very wide variety of distributed generation applications including self-powered fans for high-efficiency furnaces and water heaters and recreational vehicle power supplies, cathodic protection of pipelines, remote telemetry from oil well sites are other areas where this type of electrical generation might be used. The potential to scavenge waste heat may allow integration of this technology into general residential and commercial cogeneration schemes, although costs per kilowatt-hour would have to drop substantially from current projections.".
- Alkali-metal_thermal_to_electric_converter wikiPageID "5157393".
- Alkali-metal_thermal_to_electric_converter wikiPageLength "9279".
- Alkali-metal_thermal_to_electric_converter wikiPageOutDegree "42".
- Alkali-metal_thermal_to_electric_converter wikiPageRevisionID "678388604".
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Category:Electrical_generators.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Category:Electricity.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Category:Nuclear_technology.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Category:Thermodynamics.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Cathodic_protection.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Centimeter.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Centimetre.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Ceramic.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Cogeneration.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Combustion.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Concentrated_solar_power.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Direct_current.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Distributed_generation.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Electricity.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Electrochemical.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Electrochemistry.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Electrolyte.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Electron.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Ford.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Ford_Motor_Company.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Furnace.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Heat.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Heat_engine.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Heat_reservoir.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Ion.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Ions.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Isothermal_expansion.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Isothermal_process.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Kelvin.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Kilogram.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Liter.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Litre.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Molten_salt_battery.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Nuclear_reactor.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Oil_well.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Photovoltaic.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Photovoltaics.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Radioisotope.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Radioisotope_thermoelectric_generator.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Radionuclide.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Recreational_vehicle.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Sodium.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Solar_energy.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Solar_thermal_power.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Telemetry.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Thermal_energy_storage.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Thermal_reservoir.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Thermodynamic_cycle.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink USD.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink United_States_dollar.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Volt.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Water_heater.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Water_heating.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLink Watt.
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLinkText "Alkali Metal Thermoelectric Converter (AMTEC)".
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLinkText "Alkali-metal thermal to electric converter".
- Alkali-metal_thermal_to_electric_converter wikiPageWikiLinkText "alkali-metal thermal to electric converter".
- Alkali-metal_thermal_to_electric_converter hasPhotoCollection Alkali-metal_thermal_to_electric_converter.
- Alkali-metal_thermal_to_electric_converter wikiPageUsesTemplate Template:Citation_needed.
- Alkali-metal_thermal_to_electric_converter wikiPageUsesTemplate Template:Reflist.
- Alkali-metal_thermal_to_electric_converter wikiPageUsesTemplate Template:US_patent.
- Alkali-metal_thermal_to_electric_converter subject Category:Electrical_generators.
- Alkali-metal_thermal_to_electric_converter subject Category:Electricity.
- Alkali-metal_thermal_to_electric_converter subject Category:Nuclear_technology.
- Alkali-metal_thermal_to_electric_converter subject Category:Thermodynamics.
- Alkali-metal_thermal_to_electric_converter type Component.
- Alkali-metal_thermal_to_electric_converter type Concept.
- Alkali-metal_thermal_to_electric_converter type Machine.
- Alkali-metal_thermal_to_electric_converter type Physic.
- Alkali-metal_thermal_to_electric_converter type Thermodynamic.
- Alkali-metal_thermal_to_electric_converter type Transducer.
- Alkali-metal_thermal_to_electric_converter comment "The alkali-metal thermal-to-electric converter (AMTEC), originally called the sodium heat engine (SHE) was invented by Joseph T. Kummer and Neill Weber at Ford in 1966, and is described in US Patents 3404036, 3458356, 3535163 and 4049877. It is a thermally regenerative electrochemical device for the direct conversion of heat to electrical energy.".
- Alkali-metal_thermal_to_electric_converter label "Alkali-metal thermal to electric converter".
- Alkali-metal_thermal_to_electric_converter sameAs m.0d5g2r.
- Alkali-metal_thermal_to_electric_converter sameAs Q4727629.
- Alkali-metal_thermal_to_electric_converter sameAs Q4727629.
- Alkali-metal_thermal_to_electric_converter wasDerivedFrom Alkali-metal_thermal_to_electric_converter?oldid=678388604.
- Alkali-metal_thermal_to_electric_converter isPrimaryTopicOf Alkali-metal_thermal_to_electric_converter.