A heat exchanger unit that enables a quick interchanging of function, form and size of the different heat exchanger modules. The interchanging may be possible in regard to the sequence of the individual heat exchanger modules. The heat exchanger unit in includes inserts configured such that appropriately configured cassettes can be inserted, and an inner shape of the cassettes is configured so that different heat exchanger modules can be accommodated therein. The cassettes are thus designed specific to the heat exchanger, while the outer shape of all cassettes conforms to the shape of the uniformly configured inserts.

The Cover Handler System is mechanical mechanism that completes the task of removing large covers from industrial sized boilers, heat exchanges and condensers even in conditions cramped by walls, pipes and other boilers. The mechanism typically attaches to the top of the boiler from which will extend a swing assembly, from which horizontally extends an I-beam, along which slides a roller assembly, from which descends vertically a hanger which provides means for a bronze bushing supported cover assembly. The cover is removed and rotated out of the way by the cover handler's three means of articulation by the rotating swing assembly, the sliding roller assembly and rotating cover mounts. The cover removal system ceases to be arduous and time consuming. The complex operation of removing and replacing the cover is accomplished safely in a short amount of time even in the most cramped conditions.

A modular plate and shell heat exchanger in which welded pairs of heat transfer plates are tandemly spaced and coupled in parallel between an inlet and outlet conduit to form a heat transfer assembly. The heat transfer assembly is placed in the shell in order to transfer heat from a secondary to a primary fluid. Modules of one or more of the heat transfer plates are removably connected using gaskets at the inlet and outlet conduits which are connected to a primary fluid inlet and a primary fluid outlet nozzle. The heat transfer assembly is supported by a structure which rests on an internal track which is attached to the shell and facilitates removal of the heat transfer plates. The modular plate and shell heat exchanger has a removable head integral to the shell for removal of the heat transfer assembly for inspection, maintenance and replacement.

A cooling assembly for cooling a processor includes a heat sink base defining a first area and a second area, a plurality of heat sink fins extending from the first area, a thermoelectric cooling module having a cold side and hot side, wherein the cold side is in contact with the second area, and a heat sink module in contact with the hot side. In use, a method includes monitoring a processor parameter selected from processor power consumption and processor temperature, and causing airflow across the plurality of heat sink fins and the heat sink module. The method further includes powering on the thermoelectric cooling module in response to the processor parameter having a value greater than a first threshold value, and powering off the thermoelectric cooling module in response to the processor parameter having a value less than a second threshold value.

A heat exchanger for transferring heat between a gaseous first fluid and a liquid second fluid may include a plurality of hollow pipes extending transversely through a first fluid path for conducting the first fluid. The plurality of pipes may be coupled externally to a plurality of cooling fins arranged in the first fluid path. The plurality of pipes may internally define a second fluid path for conducting the second fluid. The plurality of pipes and the plurality of cooling fins may be arranged stacked on one another in a stacking direction to define a cooler block. The cooler block may include two side parts extending along two outer sides of the cooler block facing away from one another in the stacking direction. At least one tension rod may fixedly connect the two side parts and be configured to transmit a tensile force in the stacking direction.

A heat dissipation apparatus and a portable device are provided. The heat dissipation apparatus includes at least two heat sinks, which are connected to each other by a heat conductive tube; and a fan fixed onto one of the at least two heat sinks; the fan has an inlet vent and at least two outlet vents, the respective outlet vents have different discharging directions, a detachable shield plate is disposed at each of the outlet vents, a respective one of the outlet vents discharges an airflow outside when a respective one of the shield plates is drawn out.

A thermal control unit for controlling the temperature of a patient includes a fluid circulation channel with an inlet and outlet, a first heat exchanger, a controller, and a cartridge receptacle. The controller controls the first heat exchanger to adjust the temperature of the circulating fluid toward a desired temperature. The cartridge receptacle is adapted to receive a cartridge having a second heat exchanger and to allow fluid to flow from the cartridge into the fluid circulation channel of the thermal control unit. The cartridge may include a vacuum chamber and a coolant whereby the expansion of the coolant into the vacuum chamber cools the fluid in the cartridge. Flow of the coolant in the vacuum chamber may be automatically initiated upon insertion of the cartridge into the cartridge receptacle, or by other means.

Vessel assemblies, heat transfer units for prefabricated vessels, and methods for heat transfer prefabricated vessel are provided. A heat transfer unit includes a central rod, and a plurality of peripheral rods surrounding the central rod and connected to the central rod. The plurality of peripheral rods are movable between a first collapsed position and a second bowed position, wherein in the second bowed position a midpoint of each of the plurality of peripheral rods is spaced from the central rod relative to in the first position. The heat transfer unit further includes a heat transfer element connected to one of the plurality of peripheral rods.

A removable heatsink assembly adapted to removably receive a pipe. The removable heatsink assembly includes a first plurality of fins and a second plurality of fins having collar flanges sized to receive a pipe. The fins are received on first and second spacer rods, respectively and are hingedly connected by a hinge rod such that the first and second plurality of fins are pivotally movable about the hinge rod between an open position and a closed position. In the open position, the first and second plurality of fins are positionable over the pipe. In the closed position, the collar flanges of the first and second plurality of fins substantially surround the pipe. A fin clamp secures the first and second plurality of fins together in the closed position about the pipe.

A retainer for detachably coupling a heat absorbing/dissipating device to a heat source is disclosed. The retainer can include one or more cooling fins to enable the retainer to dissipate heat along with the heat dissipating device. The cooling fins on the retainer can be wedge-shaped or airfoil-shaped, among other things, to increase, direct, and smooth airflow over the retainer, the heat source, and the heat dissipating device. The heat dissipating device can include a heat sink with multiple cooling fins. The cooling fins on the retainer can have substantially the same geometric pattern as the cooling fins on the heat sink.