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10: Miscellaneous Energy Conversion Devices

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    This text is limited to discussing energy conversion devices that involve relatively low powers and that involve electrical energy. Furthermore, this text excludes energy conversion devices involving magnets and coils. Even within these limitations, a wide variety of energy conversion devices have been discussed. This chapter briefly mentions a few additional devices that meet these criteria. Many more devices exist, and with continued creativity and ingenuity by scientists and engineers, more will be developed in the future.

    • 10.1: Thermionic Devices
      This page discusses thermionic devices that convert thermal energy to electricity via the thermionic effect, which involves heated cathodes emitting electrons to cooler anodes. First developed by Thomas Edison in 1883, these devices achieve efficiencies up to 12%, constrained by Carnot efficiency. Common cathode materials include tungsten and barium oxide, while anodes are often copper or silver.
    • 10.2: Radiation Detectors
      This page discusses radiation detectors that convert radioactive energy into electricity for safety since humans can't detect radiation. It outlines four radiation types: alpha particles, beta particles, gamma rays, and neutrons, and how they ionize gas to create a current. It describes detector types, including ionization chambers and Geiger counters, with the latter being more sensitive.
    • 10.3: Biological Energy Conversion
      This page explains the human body's role as an energy conversion system, transforming food's chemical energy into kinetic and thermal energy. It highlights how muscles and sensory organs function as energy converters, and how the body stores energy in muscles and fat.
    • 10.4: Resistive Sensors
      This page explores different sensor types: capacitive, inductive, and resistive materials, detailing their energy conversion mechanisms. Capacitive sensors depend on changes in permittivity, area, or plate separation; inductive sensors utilize variations in permeability or thickness; and resistive sensors, like potentiometers and resistance temperature detectors, convert electrical energy to heat, with resistance altering due to physical changes.
    • 10.5: Electrofluidics
      This page covers electrohydrodynamic devices (EHDs) and their role in microfluidics by converting electrical energy into fluid flow. It explains Bernoulli's equation for fluid dynamics, using a constricted pipe as an example.

    This page titled 10: Miscellaneous Energy Conversion Devices is shared under a CC BY-NC 4.0 license and was authored, remixed, and/or curated by Andrea M. Mitofsky via source content that was edited to the style and standards of the LibreTexts platform.