A vapor-to-air heat exchanger for an aircraft powerplant that includes: a pressurized vapor source supplying vapor; and a condenser including a condenser inlet in fluid communication with the pressurized vapor source to receive the vapor, a condenser outlet, and at least one pneumatic vessel defining a cavity in fluid communication between the condenser inlet and the condenser outlet. The pneumatic vessel is reversibly inflatable to be configurable between a collapsed vessel configuration and an inflated vessel configuration. A volume of the cavity is greater in the inflated vessel configuration than in the collapsed vessel configuration. The pneumatic vessel is inflatable from the collapsed vessel configuration to the inflated vessel configuration when the cavity is pressurized by the vapor.

A matrix, configured to form at least part of a material-transfer separation unit, the matrix having a stack of several plates arranged parallel to one another in a direction known as the direction of stacking, thereby defining passages, the matrix having a length, a width and a thickness, the length of a matrix being the greatest dimension of the parallel plates, the width of the matrix being measured perpendicular to the length, and the thickness of the matrix being measured in the direction of stacking of the plates.

A heat exchanger including a plurality of fluid channel plates laminated on each other to form a cooling water fluid channel through which cooling water flows and an air fluid channel through which air flows. The fluid channel plates have a cooling water inlet hole through which the cooling water is introduced and a cooling water outlet hole through which the cooling water is discharged. Beads block the flow of the cooling water, protrude between the cooling water inlet hole and the cooling water outlet hole, are arranged to surround the periphery of the cooling water inlet hole and the cooling water outlet hole, and are spaced apart such that flow resistance of the cooling water decreases as a flow length of the cooling water increases, so that flow distribution of the cooling water can be uniform.

A heat exchanger for cooling intake air with a coolant is provided with a shell and first and second front faces, wherein one of the front faces is an inlet and the other an outlet for intake air. The shell has at least one coupling element disposed along a circumferential line of the shell that is spaced apart from the first front face by a predetermined distance. The shell has a port as an inlet or outlet for the coolant. The port is arranged at a spacing from the first front face. The spacing is larger than the predetermined distance. The shell has an insertion section between first front face and circumferential line. The shell has an internal duct system connected to the port for guiding the coolant into the insertion section. The coupling element can fixedly couple with at least one corresponding coupling element of an air duct.

A heat exchanger includes a porous material in a cold side flow passage. The porous material is configured to distribute a liquid phase throughout the cold side flow passage through capillary action.

A cold layer adapted for use in a cross counter flow heat exchanger core includes a hot inlet tent for receiving hot flow and a hot outlet tent for discharging hot flow. The cold layer is configured to receive a cold inlet flow and discharge a cold outlet flow defining a main cold flow direction. The cold layer includes a first and second cold main closure bar, each parallel to the main cold flow direction and located near the respective hot inlet or outlet tent, cold main fins perpendicular to the direction of the hot inlet flow, and cold inlet corner fins near the hot inlet tent, configured to receive a portion of the cold inlet flow in a direction that forms an angle with the main cold flow that is greater than 5 degrees.

A heat exchange module including a corrugated top heat exchange substrate and a corrugated bottom heat exchange substrate, and tubes that extend in a width direction (W) between the top and bottom substrates in heat exchanging contact with ridges of the substrates. A top and a bottom casing member contacts the substrates and each has a transverse side wall with slits oriented in the transverse direction (T) and accommodating the tubes. The side walls of the top and bottom casing members overlap and are mutually connected by soldering or brazing.

A heat exchanger for an internal combustion engine transfers heat between fluids, and includes a housing which has a housing wall and a housing interior that is bounded at least in certain regions by the housing wall. The housing interior has a fluid inlet region for the introduction of a first of the fluids into the housing interior, and a fluid outlet region for discharging the first fluid from the housing interior. The heat exchanger has at least two partitions which are at least predominantly accommodated in the housing interior and which are connected to the wall of the housing at at least one connection region. In order to separate the fluids from one another, the partitions bound, at least in certain regions, a fluid receiving space through which a second of the fluids can be made to flow. The partitions are connected to one another at least at a joining region that is assigned to the fluid inlet region and that adjoins the fluid receiving space in a main flow direction of the first fluid. The heat exchanger additionally has a stiffening element which, in order to stiffen a stiffening portion of the joining region adjoining the connection region, is arranged at the joining region and is configured to brace the stiffening portion at least against a buckling load arising from a change in length in the event of a temperature-induced change in length of the joining region.

Methods and devices heat or cool viscous materials, such as meat emulsions useful for producing food and other products. The devices have a heat exchanger including a first plate, a second plate attached to the first plate, and a first spacer and a second spacer arranged between the first plate and the second plate. The first plate, the second plate, the first spacer, and the second spacer define at least one temperature controlled passage for a product to pass through the heat exchanger.

A multilayer heat exchanger device comprising: a stack of plates arranged to provide multiple fluid flow paths separated by the plates; wherein at least some of the plates are pin fin plates that each have an array of pins extending outwards from the pin fin plate into the fluid flow paths; and wherein each pin comprises an inner end integrally formed with the pin fin plate, a mid-point along a longitudinal axis of the pin, and an outer end to be bonded to an adjacent plate; wherein the cross sectional area of the pin at the outer end is larger than the cross sectional area at the mid-point.