L
Lynn E. Terry
Researcher at Lynn University
Publications - 3
Citations - 105
Lynn E. Terry is an academic researcher from Lynn University. The author has contributed to research in topics: Hydrogen turboexpander-generator & Volume (thermodynamics). The author has an hindex of 3, co-authored 3 publications receiving 105 citations.
Papers
More filters
Patent
Power cycles based upon cyclical hydriding and dehydriding of a material
Lynn E. Terry,Roger J. Schoeppel +1 more
TL;DR: Improved power cycles for improving the production of power and refrigeration and for conserving thermal energy, utilizing as a common basic characteristic, a hydride-dehydride-hydrogen power cycle in which hydrogen is reversibly combined with a homogeneous forming material at a relatively low temperature and pressure, the hydrided material is then heated at constant volume to chemically compress the hydrogen, and finally the material is dehydrided by further heating the material to release hydrogen gas at relatively high pressure and temperature as mentioned in this paper.
Patent
Hydride-dehydride power system and methods
Lynn E. Terry,Roger J. Schoeppel +1 more
TL;DR: In this article, a power system comprising a reactor for chemically forming a hydride by reaction with hydrogen at a relatively low pressure and relatively low temperature, means for heating the hyddride while retaining it at a constant volume to effect chemical compression of the hydrogen, and a power generating, gas expansion device connected to the reactor for receiving hydrogen under pressure therefrom, and expanding it to derive power therefrom.
Patent
Power cycles based upon cyclical hydriding and dehydriding of material of a material
Lynn E. Terry,Roger J. Schoeppel +1 more
TL;DR: Improved power cycles for improving the production of power and refrigeration and for conserving thermal energy, utilizing as a common basic characteristic, a hydride-dehydride-hydrogen power cycle in which hydrogen is reversibly combined with a homogeneous forming material at a relatively low temperature and pressure, the hydrided material is then heated at constant volume to chemically compress the hydrogen, and finally the material is dehydrided by further heating the material to release hydrogen gas at relatively high pressure and temperature.