A rotating heat carrier system includes a barrier having a first side portion and a second side portion. A plurality of disks is mounted to a shaft. A motor is coupled to the shaft. The motor is operable to rotate the shaft and the plurality of disks. The plurality of disks is at least partially positioned within the barrier. A first portion of each of the plurality of disks extends along a radial direction away from the first side portion of the barrier. A second portion of each of the plurality of disks extends along the radial direction away from the second side portion of the barrier.

The present application generally relates to a method and apparatus for providing an active heat exchanger with dynamic positioning to improve vehicle aerodynamics. More specifically, aspects of the present disclosure relate to systems, methods and devices for a vehicle fascia having multiple airflow openings, at least one of having an active shutter system and wherein the active heat exchanger is positioned to respond to closing of one or more of the airflow openings when active aerodynamics are deployed.

The present application generally relates to a method and apparatus for providing an active heat exchanger with dynamic positioning to improve vehicle aerodynamics. More specifically, aspects of the present disclosure relate to systems, methods and devices for a vehicle fascia having multiple airflow openings, at least one of having an active shutter system and wherein the active heat exchanger is positioned to respond to closing of one or more of the airflow openings when active aerodynamics are deployed.

An example apparatus may include a first plate having a first side. A first plurality of fins may be integral with the first side of the first plate and protruding perpendicularly therefrom. The first plurality of fins may be arranged in first concentric circles separated radially by a first distance. The apparatus may also include a second plate having a first side. The second plate may be rotatably coupled to the first plate. A second plurality of fins may be integral with the first side of the second plate and protruding perpendicularly therefrom. The second plurality of fins may be arranged in second concentric circles separated radially by the first distance. Each fin of the second plurality of fins may interpose between adjacent fins of the first plurality of fins to transfer heat between the second plate and the first plate.

A rotating heat carrier system includes a barrier having a first side portion and a second side portion. A plurality of disks is mounted to a shaft. A motor is coupled to the shaft. The motor is operable to rotate the shaft and the plurality of disks. The plurality of disks is at least partially positioned within the barrier. A first portion of each of the plurality of disks extends along a radial direction away from the first side portion of the barrier. A second portion of each of the plurality of disks extends along the radial direction away from the second side portion of the barrier.

A rotary heat exchanger includes a hub configured to be rotatably driven by a shaft, a fan including a plurality of fan blades integrally coupled to the hub and extending radially outwardly therefrom, and a heat exchanger including a plurality of heat exchanger sections. The heat exchanger includes a plurality of cooling fins for receiving air from the fan. Each of the plurality of heat exchanger sections is located between two of the plurality of fan blades. The hub, the fan, and the heat exchanger are integrally formed as a single body by a three-dimensional printing process.

Contoured fan blades and associated systems and methods are disclosed herein. A representative embodiment includes a hub and multiple curved fan blades circumferentially arranged around, and coupled to, the hub. Individual fan blades can have a tip, a first curved edge, and a second curved edge. The first and second curved edges extend over at least part of the length between the hub to the tip of the fan blade. The fan blade is formed with multiple upper channels and multiple lower channels. The multiple upper and lower channels extend from the first curved edge to the second curved edge.

A heat exchanging system includes a tank including a fluid inlet and a fluid outlet, which encloses (envelopes) a heat exchanger including a manifold tube and one or more one heat exchanging plates, extending from the manifold tube. The manifold tube includes a fluid intake and the fluid outlet, as well as a manifold barrier, which divides the interior of the manifold tube (for example, which is hollow), so as to define within the manifold tube an intake region and an outlet region. The heat exchanging system also has at least one heat exchanging plate extending from the manifold tube, the at least one heat exchanging plate with at least one plate barrier, such that the heat exchanging plate is configured to define a fluid flow path within the heat exchanging plate such that fluid flows from the intake region of the manifold tube.

A solids heat exchanger (10) is in the form of a shell and tube arrangement having a shell section (11) through which heated oil (12) passes and a tube section (13). A screw conveyor (14) extends along its length and has a drive motor (15). Drill cuttings or other hydrocarbon contaminated materials are fed in through an inlet (16) and then conveyed along the tube (13) where heat transfer takes place. On exiting the tube (13) oil and water vapour rises and escapes through a first outlet (17) while the now cleaned drill cuttings or other materials fall through a second outlet (18) forming a discharge zone. The apparatus aims to reduce the oil content of the solids to less than 0.5%. The solids can then simply be disposed of. The base oil can be reclaimed and reused.

A beverage container cooling unit has: (a) a housing having a slot for receiving a container therein, (b) a cooling element having a cold supply, (c) a heat conductive panel enabling heat transfer between a container provided in the slot and the cold supply; wherein the heat conductive panel has two material layers fixed against one another: (I) a first material layer defining a cooling surface facing the container receiving slot and an opposed surface, said first layer made of a material having a thermal expansion coefficient of X.sub.1; (ii) a second material layer having a contact surface facing positioned against the opposed surface of the first material layer and a second opposed surface, the second material layer having a thermal expansion coefficient of X.sub.2, different from X.sub.1, the difference in thermal expansion causing the conductive panel to bulge at a change in temperature.