A shell heat dissipating structure of a small form-factor transceiver includes a hollow shell and a heat dissipating structure. The hollow shell has a setting surface disposed on the outside; the setting surface is formed along an extending direction of the hollow shell. The heat dissipating structure has plural fins formed along the extending direction of the hollow shell and spaced on the setting surface; a plurality of channels is formed among the fins. Each of the fins is formed by plural projecting portions and recess portions disposed along the extending direction and alternated continuously such that the channels among the fins communicate with each other through the recess portions.

A heat exchanger includes tube expansion portions provided respectively on a plurality of heat transfer tubes such that outer peripheral surfaces of the heat transfer tubes are respectively pressed against inner peripheral surfaces of a plurality of first holes provided in a side wall portion of a case, and a plurality of first concave surface portions provided in an outer surface of the tube expansion portion so that first gaps, into which brazing material of a first brazed portion advances, are formed between the outer surface of the tube expansion portion and the inner peripheral surface of the first hole. At least one of the plurality of first concave surface portions is positioned in an outside peripheral surface portion of the outer peripheral surface of the heat transfer tube. According to this configuration, the strength with which the heat transfer tubes are attached to the case can be increased while simplifying a manufacturing operation and reducing the manufacturing cost.

A heat exchanger includes a core defining a first passageway configured for a first fluid to flow through and a second passageway configured for a second fluid to flow through. The core includes a plurality of unit cells coupled together. Each unit cell of the plurality of unit cells includes a sidewall at least partly defining a first passageway portion, a second passageway portion, a plurality of first openings for the first fluid to flow through, and a plurality of second openings for the second fluid to flow through. Each unit cell of the plurality of unit cells is configured to enable the first fluid to combine and divide in the first passageway portion. Each unit cell is further configured to enable the second fluid to combine and divide in the second passageway portion.

An exhaust gas heat exchanger may include a housing and a heat exchanger block arranged therein, the heat exchanger block including tube plates and a tube bundle having a plurality of flat tubes held at longitudinal ends of the flat tubes in rim holes formed in a complementary manner thereto in the tube plates. A first flow path for exhaust gas may extend in the flat tubes, and a second flow path for coolant may extend around the flat tubes and within the housing. The housing may include a plurality of latching contours, which interact with a plurality of counterpart latching contours arranged on an associated tube plate to fix the tube plates and the heat exchanger block on the housing.

An exhaust gas recirculation (EGR) cooler includes: a housing having an exhaust gas inlet and an exhaust gas outlet, a coolant inlet and a coolant outlet, and a plurality of grooves protruding inward from upper and lower surfaces of the housing; a plurality of tubes spaced apart from each other so that exhaust gas flows in the housing; and a plurality of supporters supporting the plurality of tubes in the housing, wherein the plurality of supporters are disposed between an upper surface of the housing and a tube adjacent the upper surface of the housing among the plurality of tubes, between an lower surface of the housing and a tube adjacent the lower surface of the housing among the plurality of tubes, and between the plurality of tubes so that the plurality of supporters are disposed in a space in which the coolant flows inside the housing.

A heat exchanger includes a header, a plurality of tubes, and a reinforcement member. The header has a face plate that defines a plurality of orifices, a top plate that extends away from an end of the face plate, and a projection that extends outward from the top plate. Each of the plurality of tubes extend into a respective one of the plurality of orifices. The reinforcement member has a backing plate that is secured to the top plate, a brace that extends from the backing plate and is secured to a first of the plurality of tubes, and a protrusion that extends outward from the backing plate. The protrusion engages the projection to restrict movement of the reinforcement member in a longitudinal direction relative to the tubes.

A syngas cooler system includes a pressure vessel, a conduit, a plenum, a plenum, a conduit, and a bellows assembly. The pressure vessel includes a throat and a dome adjacent to the throat. The throat includes an area of excess heat, and the dome includes an area of deficient heat. The plenum extends between the throat and the bellows assembly. The bellows assembly is coupled at least partially within the dome. The conduit is coupled to the plenum for channeling a flow of purge fluid from external to the pressure vessel into the plenum such that purge fluid transfers heat from the area of excess heat into the area of deficient heat to facilitate reducing temperature differential stresses within the dome and the pressure vessel.

A heat exchanger manifold for use in a heat exchanger having a plurality of microtubes includes a receiving component for supporting and forming a seal about each of the plurality of microtubes and a circuiting component having at least one recessed channel for defining an enclosed flow configuration of a fluid of the heat exchanger. The receiving component is joined and sealed to the circuiting component such that an internal flow passage of the plurality of microtubes is arranged in fluid communication with the at least one recessed channel.

The present invention relates to a heat exchanger (1) comprising: a tube bundle (2) comprising a plurality of tubes (2) placed parallel to one another, said tube bundle (2) comprising fins (6) placed between the tubes (2); two collectors (3), one collector (3) being placed on both sides of the tube bundle (2), each collector (3) comprising a collector plate (4), said collector plate (4) comprising orifices inside which the ends of the tubes (2) are introduced, and a rim (41) forming a groove (42) which is designed to receive a cover (8); and at least one reinforcement plate (10) placed between a collector plate (4) and the fins (6), parallel to the collector plate (4) and brazed against at least part of the tubes (2) of the tube bundle (2) and said collector plate (4),
the at least one reinforcement plate (10) comprising a lateral wall (101) which projects in the direction of the collector plate (4), and covers the rim (41) of the collector plate (4) at least partially, said lateral wall (101) being brazed against said rim (41) of the collector plate (4) in order to secure the reinforcement plate (10) on the collector plate (4).

A heat exchanger assembly including a heat exchanger that has a first end and a second end opposite the first end, and a cover coupled to the second end. The heat exchanger also includes a plurality of fins with a first fin disposed adjacent the first end and a second fin disposed adjacent the second end, and a continuous, serpentine coil. The coil includes first return bends projecting beyond the first fin and second return bends projecting beyond the second fin. The cover has a base plate and separate receptacles encasing one or more of the second return bends to permit airflow through the encased second return bends. The base plate is positioned on the second end to inhibit airflow from one of the receptacles to another of the receptacles.