In one or more embodiments, a disclosed method for cooling a vehicle involves routing, by a bypass line, boil-off of a cryogenic fuel of the vehicle past a cold plate to cool a subsystem mounted proximate the cold plate. The method further involves purging the boil-off in a direction away from the vehicle, after the boil-off passes the cold plate. In one or more embodiments, the cryogenic fuel involves liquid hydrogen (LH2), liquid oxygen (LO2), and/or liquid methane (LCH4). In at least one embodiment, the boil-off of the cryogenic fuel involves gaseous hydrogen (GH2), gaseous oxygen (GO2), and/or gaseous methane (GCH4). The vehicle is a space vehicle, an airborne vehicle, a terrestrial vehicle, or a marine vehicle. In at least one embodiment, the vehicle is a fuel cell vehicle (FCV).

In one or more embodiments, a disclosed method for cooling a vehicle involves routing, by a bypass line, boil-off of a cryogenic fuel of the vehicle past a cold plate to cool a subsystem mounted proximate the cold plate. The method further involves purging the boil-off in a direction away from the vehicle, after the boil-off passes the cold plate. In one or more embodiments, the cryogenic fuel involves liquid hydrogen (LH2), liquid oxygen (LO2), and/or liquid methane (LCH4). In at least one embodiment, the boil-off of the cryogenic fuel involves gaseous hydrogen (GH2), gaseous oxygen (GO2), and/or gaseous methane (GCH4). The vehicle is a space vehicle, an airborne vehicle, a terrestrial vehicle, or a marine vehicle. In at least one embodiment, the vehicle is a fuel cell vehicle (FCV).

A flexible thermoelectric device is disclosed that can cover a large surface area of a user's body. The flexible thermoelectric device allows for efficient cooling in a form factor that is comfortable, durable, and easy to use. The device includes a myriad of embodiments. In one embodiment, the thermoelectric device includes a plurality of modules wherein each module includes a thermally conductive plate, a heat sink, and a thermoelectric component disposed between. The plurality of modules is disposed on an elastic material. At least one of a plurality of spacers is disposed on the thermally conductive plate of each of the plurality of modules. The elastic material is coupled to the plurality of modules, the plurality of spacers, or a combination thereof. One or more power sources are electrically coupled to a plurality of modules for providing power to the thermoelectric components.

A thermal transistor is provided. The thermal transistor includes a metallic thermal conductor, a non-metallic thermal conductor, and a thermal resistance adjusting unit. The metallic thermal conductor and the non-metallic thermal conductor are contact with each other to form a thermal interface. The thermal resistance adjusting unit is configured to generate an electric field at the thermal interface.

A thermal transistor is provided. The thermal transistor includes a metallic thermal conductor, a non-metallic thermal conductor, and a thermal resistance adjusting unit. The metallic thermal conductor and the non-metallic thermal conductor are contact with each other to form a thermal interface. The thermal resistance adjusting unit is configured to generate an bias voltage U.sub.12 between the metallic thermal conductor and the non-metallic thermal conductor.

A system is provided for rapidly cooling a pot or boiler. The system includes a cylindrical or semi-cylindrical tube operatively connected to the pot or boiler. The tube also includes a means for attaching a water source or hose. Finally, the tube may also include a series of holes or nozzles for directing a stream or spray of water towards the outer surface of the pot or boiler. The system may be built into the pot or boiler or may be a standalone, removable and adjustable system for use on multiple different pots or boilers.

A gas production line including: an inlet; an outlet; and a wet gas condenser connected between the inlet and the outlet, wherein the wet gas condenser includes: a condensing chamber; a condensing surface; and a collecting chamber, wherein, in use, water vapour in wet gas passing over the condensing surface is condensed into liquid water, the liquid water flowing along a predetermined flow path into the collecting chamber.

A system for controlling temperature of a body (6) comprising a DBD actuator (9) connectable to a power source to produce an ionic wind on the body; a control unit (8) to select an initial configuration and to control the power source (5) depending on a temperature difference (?T) between an input temperature (T.sub.i) and a target temperature (T.sub.ta) on the body (6), wherein the initial configuration comprises the following constructive parameters of the DBD actuator: number, shape, geometry, relative position of electrodes (d), dielectric material, dielectric thickness (e), wherein the initial configuration further comprises the following setting parameters to be set in the power source (5): a frequency value (f), an amplitude value (V), a waveform signal and a duty cycle, wherein the control unit (8) adjusts the initial configuration by modifying any of the setting parameters to control the heat transferred to the surface of the body.

A fixture for use in heating an article, which article has two open ends and portions that define an interior space. The fixture includes a first component and a second component. The first component includes a first cover for covering one open end of an article. The second component includes a second cover for covering another open end of the article. At least one of the first and second components includes a mechanism for joining the first and second components together around the article in a spaced apart relationship. At least one of the components includes a port for transferring heat into the interior space of the article. A method of using the fixture for heating a portion of a turbine engine in order to service the same is also provided.

Systems and methods for generating a thin film of a fluid are described. In an embodiment, a fluid support structure may be configured to receive a fluid, such as water, at a top surface and to support the fluid over at least a portion of the top surface. Channels may be formed in the top surface of the fluid support structure. Wiper blades may be configured to move over the top surface in contact with at least a portion of the fluid to form the fluid into a thin film. The wiper blades may include protrusions corresponding to the channels. As the wiper blades move over the top surface, the protrusions may move within the channels forming a thin film of the fluid within the channels. According to some embodiments, the fluid support structure may be configured as an evaporation surface configured to facilitate the evaporation of the fluid.