The JTEC converts heat into electrical energy by compressing and expanding hydrogen gas. It operates as a closed system with no moving classical mechanical parts, requires no input of fuel, and creates no exhaust. The engine consists of two stages: A low-temperature compression stage and a high-temperature power stage. Each stage consists of a working fluid chamber that a copper lined membrane electrode assembly bisects. A MEA is a proprietary ceramic proton exchange membrane that is sandwiched between two electrodes. In the high-temperature power stage, expanding high pressure hydrogen from the compression stage converts the heat energy into electrical energy via the MEA. As the high-temperature, high pressure hydrogen is forced through the PEM it is ionized, producing protons and electrons. The protons pass through the membrane while the electrodes expel the electrons through a load. After passing through the PEM, the protons recombine with the electrons to produce low pressure hydrogen gas that flows out to the compression stage. From the perspective of the high-temperature stage, the load consists of the external load on the engine and the low-temperature compression stage. In the compression stage, electrical potential is applied across the MEA and forces protons to flow through the PEM to produce high pressure hydrogen. As the hydrogen travels between the stages, it passes through a heat exchanger that increases efficiency by helping to keep the high-temperature stage hot and the low-temperature stage cool. The amount of energy available to the external load is the difference in electrical potential between that needed to compress hydrogen at low-temperature and that which expanding it at high temperature generates. Unlike other heat pump devices, the JTEC requires an initial input of electrical energy to start the compression stage and initiate the cycle. The engine can also be operated in reverse to convert electrical energy into a temperature differential, for example in HVAC applications. In the proposed application, solar irradiance would heat the power stage, and the compression stage would connect to an ambient temperature heat sink.
Applications
The scalability of the engine leads its developers to claim that its potential applications range from providing power for microelectromechanical systems to functioning as large-scale power plants. The converter can use many diverse forms of fuel without the need for fuel-specific customization as seen in internal combustion engines, and can generate power from fuel combustion, solar irradiance, low grade waste heat from industry, or such other power generation systems as fuel cells, internal combustion engines, or turbines, because it functions as an external combustion engine.
