A plate heat exchanger and methods of construction and use which allow the plate assemblies used in the exchanger to be easily cleaned and maintained and which allow the plate assemblies to be individually and separately removed from the exchanger for cleaning or maintenance while the exchanger remains online and while the other plate assemblies in the plate heat exchanger continue to operate.

A transfer-of-mass system for increasing rotational energy output thereof includes a sealed container having a central axis and an outer wall radially spaced apart from the central axis. A liquid partially fills the container. A motor causes the container to rotate about its central axis at a speed of rotation such that the liquid is acted upon by centrifugal forces to move it to the container's outer wall. Energy is applied to the liquid to cause at least a portion of the liquid at the container's outer wall to move towards the container's central axis wherein the container rotates faster than the speed of rotation caused by the motor.

A heat exchanger includes a plate with an external surface, a channel, and a nozzle. The external surface bounds an interior of the plate. The channel is disposed in the heat exchanger and passes through a portion of the interior. The nozzle is integrally disposed in the heat exchanger, extends through a portion of the external surface, and is fluidly connected to the channel. The nozzle is configured to transport a liquid from the channel, through the external surface, and to distribute the liquid onto a portion of the heat exchanger.

A plate heat exchanger and methods of construction and use which allow the plate assemblies used in the exchanger to be easily cleaned and maintained and which allow the plate assemblies to be individually and separately removed from the exchanger for cleaning or maintenance while the exchanger remains online and while the other plate assemblies in the plate heat exchanger continue to operate.

Systems and methods for reducing the pressure of a first pressurized fluid, thereby reducing the temperature of the pressurized fluid, and utilization of the reduced-pressure and temperature fluid to cool a second fluid. Such an approach can enable a reduction in the size and weight of a hydraulic system, utilize waste energy in a system, and/or minimize electrical power requirements of a system, among other benefits.

In a method of manufacturing a heat exchanger for a rotating electrical machine, a pressing device is placed inside a tube with elastic members compressed so that a first pressing part and a second pressing part press the tube mutually oppositely in directions in which the diameter of at least a part of the tube located between two through holes of two supporting members expands. Pressure is built up in the tube and the tube is plastically deformed to form an inside large diameter part and inside connecting parts.

An heat exchanger and method for forming the heat exchanger, the heat exchanger including a cooling architecture comprising at least one unit cell having a set of walls with a thickness, the set of walls defining fluidly separate conduits having multiple openings, each of the multiple openings having a hydraulic diameter, wherein an average fluid temperature (T.sub.f) to material temperature limit (T.sub.m) ratio (T.sub.f/T.sub.m) is greater than 0 and less than or equal to 1.25 (0<T.sub.f/T.sub.m≤1.25), and wherein the thickness (t) and the hydraulic diameter (D.sub.H) relate to each other by an equation:

[00001]$\frac{T_f}{T_m}.Math.\frac{D_H^{2/3}\left(D_H+t\right)}{{\left(D_H+2t\right)}^{8/3}}$

to define a unit cell performance factor (UCPF).

The present invention provides a heat transferring device and a method for making thereof. The heat transferring device has a thermal conducting substrate and a porous layer. The thermal conducting substrate has a plurality of protrusions and concave bottom surfaces. The concave bottom surfaces are located between the protrusions. The porous layer is embedded between the protrusions. The present invention also provides a high temperature material transferring system comprising a cylindrical container and the heat transferring device disposed on the surface of the cylindrical container.

Power Plant Cooling Systems are designed to replace Once-Through Cooling systems and/or cooling towers currently used to cool power plants that generate electricity. The intake and discharge piping of the cooling water would be connected by piping/tubing that would serve as a geothermal loop that would be underground and/or in a body of water next to the power plant that would serve as a heat exchange medium. An alternative embodiment would use a latticework of piping/tubing over the turbine hall (equipment building) and/or the containment building(s) to serve as a heat exchange medium when the atmospheric conditions are proper.

Systems and methods for reducing the pressure of a first pressurized fluid, thereby reducing the temperature of the pressurized fluid, and utilization of the reduced-pressure and temperature fluid to cool a second fluid. Such an approach can enable a reduction in the size and weight of a hydraulic system, utilize waste energy in a system, and/or minimize electrical power requirements of a system, among other benefits.