Abstract: A heat exchanger with multi-flow capabilities includes a pair of intermediate tanks located between a pair of header tanks. An open gap is provided between the two intermediate tanks. A first plurality of tubes extend between the header tanks. A second plurality of tubes extend between one of the header tanks and one of the intermediate tanks. A third plurality of tubes extend between the other header tank and the other intermediate tank. In a two flow system, the two intermediate tanks are in fluid communication through a flexible jumper tube. In a three flow system the two intermediate tanks are isolated from each other. The open gap between the intermediate tanks allows for the uneven heat expansion between the various fluid flows.

Abstract: A heat exchanging device includes first and second disk members coupled together to form a disk unit having a chamber. The first disk member has an inlet and the second disk member has an outlet. At least one of the disk members has first and second connecting members coupled to the other disk member. The connecting members are arranged on opposite sides of a line extending axially through the inlet and outlet to define therebetween an inlet flow path above the line and outlet flow path below the line. A medium directing member is disposed within the disk unit. The medium directing member, the first and second connecting members and the chamber are arranged such that heat exchange media is directed to flow from the inlet, through the inlet flow path, through the chamber, through the outlet flow path, and into the outlet.

Abstract: A high-temperature and high-pressure corrosion-resistant process heat exchanger for a nuclear hydrogen production system decomposes sulfite (SO3) using heat from a high-temperature gas-cooled reactor to thereby produce sulfide (SO2) and oxygen (O2). The process heat exchanger comprises second and third system coolant channels, each of which is defined by a heat transmission fin, which is bent in a quadrilateral shape, and heat transmission plates, and has increased corrosion resistance thanks to ion-beam coating and ion-beam mixing using a material having high corrosion resistance. The third system coolant channel includes reaction catalysts for SO3 decomposition, and is made of a super alloy. Thus, a system differential pressure between the second and third system coolant channels can be greatly maintained at a high temperature of 900° C. or higher.

Abstract: Tube heat exchanger comprising finned tubes, wherein the tubes extend in a certain axial direction and are provided with heat exchange fins. Each fin has a heat exchange surface surrounding a tube that extends in a certain radial direction in relation to the tube and which is relief structured to form grooves spaced apart from one another in said radial direction. The grooves of a fin have different dimensions that decrease on moving away from the tube in said radial direction so as to form a guide for a fluid around the tube.

Abstract: A heat sink includes a base having a first surface thermally connected to a heat producing component and a plurality of fins supported by a second surface of the base and arranged in a predetermined direction, each fin having a plurality of through-holes. The base and the plurality of fins are integrally formed from a porous material, for example a lotus-shaped porous material. The heat sink is placed within a duct. The heat sink may have a width of about 10 mm or less.

Abstract: The shell and tube heat exchanger includes a shell having a fluid inlet and a fluid outlet, and a plurality of tubes disposed inside the shell, the tubes having a fluid inlet and a fluid outlet. An impingement baffle having a plurality of perforations is disposed in the shell between the shell fluid inlet and the tubes. The impingement baffle is configured to guide a heat exchanger fluid from the shell fluid inlet to distribute the heat exchanger fluid uniformly around the tubes. The perforations prevent recirculation and stagnation of fluid flow behind the baffle, thereby preventing fouling and corrosion with subsequent thinning of the tube walls.

Abstract: An integrated heat exchanger has a first heat exchanger and a second heat exchanger. The first heat exchanger has a first bracket and a second bracket on header parts thereof, respectively. The first bracket and the second bracket are connected to header parts of the second heat exchanger with a first bolt and a second bolt, respectively, for integrating the first heat exchanger with the second heat exchanger. The header parts of the second heat exchanger are provided with a first bolt-receiving portion and a second bolt-receiving portions for receiving the first bolt and the second bolt therein, respectively. The first bolt-receiving portion and the second bolt-receiving portion define a first axis and a second axis, respectively. The first axis and the second axis are nonparallel to each other. Thus, the first bolt and the second bolt are disposed nonparallel to each other.

Abstract: A cooling mechanism includes a first heat exchanger, a first fluid-flow port, and a second fluid-flow port. The first heat exchanger includes a forced-fluid driver and is configured to pump heat from inside an enclosed area to outside of the enclosed area. Furthermore, the first fluid-flow port is configured to accommodate a first fluid flow into the enclosed area and the second fluid-flow port is configured to accommodate a second fluid flow from the enclosed area. Note that the first fluid-flow port and the second fluid-flow port are approximately coplanar. In addition, a given fluid-flow port, which may be either or both of the fluid-flow ports, is tapered to have an associated cross-sectional area which is smaller at an edge of the given fluid-flow port that is proximate to the outside of the enclosed area than at an edge of the given fluid-flow port that is proximate to the inside of the enclosed area.

Abstract: A heat exchanging device includes first and second disk members coupled together to form a disk unit having a chamber. The first disk member has an inlet and the second disk member has an outlet. A medium directing member is disposed within the disk unit. A first end of the medium directing member has a first channel formed at an angle to direct heat exchange media flowing in from the inlet to the chamber, and a second end of the medium directing member has a second channel formed at an angle to direct the heat exchange media out of the chamber through the outlet. A plurality of disk units are coupled together in a row. Multiple rows of the heat exchanging devices may be disposed between manifolds.

Abstract: Apparatus for propping a device, comprising a platform, a bracket, a carriage and a backstay. The backstay is rotatable relative to the carriage and to the device. The carriage can be moved in a first direction, which can causes a device to move between a stowed position and a deployed position. Apparatus comprising a rotatable assembly and a device movable between stowed and deployed positions, a center of rotation of the device in the deployed position being at or displaced only substantially vertically from a center of gravity of the rotatable assembly. Apparatus comprising a platform mounting portion, a platform structure rotatably mounted thereon, a duct extending through the platform mounting portion and into a space within the platform structure, whereby fluid can be passed through the duct and into the enclosed space while the platform structure is rotating relative to the mounting portion. Methods of propping a device.

Abstract: A heat sink includes a base with a plurality of recesses defined therein, a plurality of columned fins each having a head and a body extending from the head, and a cover joining with the base. Each head is received in and higher than a corresponding recess of the base. The heads are sandwiched between the cover and the base, whereby the columned fins are secured on the base. A portion of the cover contacting the head of each of the columned fins protrudes to form a deformed part. A method of manufacturing the heat sink is also disclosed.

Abstract: An exemplary heat sink includes elongated fins stacked together. Each of the fins includes a first dissipating portion and a second dissipating portion arranged in turn along a longitudinal axis of the fin. The first dissipating portion and the second dissipating portion of each fin are offset from each other along a stacked axis of the fins. An opening is defined in each fin between the first dissipating portion and the second dissipating portion thereof.

Abstract: A heat exchanger assembly includes a core assembly having air passages that are closed off on at least one side by a closure bar. A reinforcing bar is received within a channel of the closure bar to create an interface with substantially no gaps that may accumulate moisture within the core assembly. The prevention of moisture accumulation at the interface between the reinforcing bar and the closure bar prevents potential damage caused by freezing.

Abstract: A heat exchanger is disclosed. The heat exchanger may have an inlet configured to receive a first fluid and an outlet configured to discharge the first fluid. The heat exchanger may further have at least one passageway configured to conduct the first fluid from the inlet to the outlet. The at least one passageway may be composed of a graphite foam and a layer of graphite material on the exterior of the graphite foam. The layer of graphite material may form at least a partial barrier between the first fluid and a second fluid external to the at least one passageway.

Abstract: In a plate laminate type heat exchanger a plurality of groove-like protrusions is formed on one side of each of flat core plates, and the protrusions extend substantially in parallel to one another from one end side in the longitudinal direction of the plate toward the other end side in the longitudinal direction of the plate, form a U-turn region in an area on the other end side in the longitudinal direction of the plate, and return to the one end side in the longitudinal direction of the plate. The plate is curved in such a way that ridges and valleys are formed on part of the plate, the area in which the protrusions are formed but the U-turn region is not formed, in the direction in which the plate is laminated and the ridges and valleys are repeated along the longitudinal direction. Both ends of each of the protrusions converge into an inlet port for high temperature fluid and an outlet port for high temperature fluid, respectively.

Abstract: A flat tube for a heat exchanger having a stack of such flat tubes. The flat tube has a plurality of spaced-apart dimples formed on each of its opposite faces. At least some of the dimples on each face have an elongate plan shape, at least some of the elongate dimples being obliquely oriented such that their major axes form oblique angles with a longitudinal axis of the tube. The obliquely oriented elongate dimples are positioned such that when two of the tubes are stacked, the obliquely oriented elongate dimples on opposing faces of the tubes contact one another and the major axes of each contacting pair of elongate dimples are non-parallel to each other. Each contacting pair of elongate dimples of adjacent tubes thus forms a “cross” or “X”.

Abstract: A heat sink for dissipating a thermal load is disclosed that includes one or more heat sink bases configured around a central axis of the heat sink so as to define an interior space, at least one heat sink base receiving the thermal load, a thermal transport connected to the at least one heat sink base receiving the thermal load so as to distribute the thermal load in the heat sink, and heat-dissipating fins connected to each heat sink base, the heat-dissipating fins extending from each heat sink base into the interior space of the heat sink, each heat-dissipating fin shaped according to the location of the heat-dissipating fin with respect to the location of the thermal load and the location of the distributed thermal load in the heat sink.

Abstract: A heat exchanger is provided which has an easy-to-manufacture structure, is inexpensive, and has high quality and reliability while keeping high heat exchanging performance. The heat exchanger has first substrates (26) having first slits (30) and second slits (40) disposed substantially in parallel, and second substrates (28) having third slits (50) with substantially the same shape as that of first slits (30). The longitudinal length of second substrates (28) is set shorter than that of second slits (40). First substrates (26) and second substrates (28) are stacked so that first slits (30) communicate with third slits (50). First slits (30) and third slits (50) form tube external flow channels (60). Second slits (40) and second substrates (28) form tube internal flow channels (70). The heat exchanging section including only tubes can be formed of substrates having a slit, so that the heat exchanger can be manufactured easily and inexpensively.

Abstract: A fan attachment is provided to attach a fan assembly to a cap of a heat exchanger. The fan attachment includes a feature to manage wires going to the fan motor, a notch for a thermister to sense temperature, snap hooks to be engaged by receiving tabs of the cap, a keying shear load feature to radially align the fan attachment and cap, and Z-height tolerance springs to bias the fan attachment away from the cap. The cap has features to interact with those of the fan attachment, including receiving tabs. The fan attachment may be manually aligned and forced so that the snap hooks are received and engaged by the receiving tabs. Additionally, the snap hooks and keying feature are, in combination, capable of supporting fan and attach mechanism in an undamaged condition during 25 g-force shock to the heat exchanger.

Abstract: A latch mechanism includes a press portion, two connection portions, and two latch portions. The two connection portions are connected to opposite ends of the press portion correspondingly. Each connection portion includes two connectors. First ends of the two connectors are connected together to form a coupling end to connected to a corresponding end of the press portion. Each latch portion is selectively connected to the second end of one of the two connectors of a corresponding connection portion.