The disclosed embodiments relate to a system that provides a polymer heat exchanger with internal microscale flow passages. The system includes a set of plates comprised of a polymer that includes internal microscale flow passages, which are configured to carry a liquid. The set of plates is organized into a stack, wherein consecutive plates in the stack are separated by fins to form intervening air passages. The system includes a liquid flow pathway, which flows from a liquid inlet, through the internal microscale flow passages in the stack of plates, to a liquid outlet. It also includes an airflow pathway, which flows from an airflow inlet, through the intervening air passages between the consecutive plates in the stack of plates, to an airflow outlet. The liquid flow pathway flows in a direction opposite to a direction of the airflow pathway to provide a counterflow design that optimizes heat transfer between the liquid flow pathway and the airflow pathway.

A method of forming a thermal energy storage unit for a surface to be cooled or heated includes using an additive manufacturing process to form a plurality of non-rectilinear structures having a plurality of thermally conductive substructures, the substructures defining a plurality of interior cavities within the substructures and a plurality of exterior fluid channels that cross over or under the plurality of interior cavities, arranging the plurality of non-rectilinear structures in a plurality of housings, wherein each of the plurality of non-rectilinear structures is arranged in a corresponding one of the plurality of housings, and connecting the plurality of housings to each other to build up the thermal energy storage unit whereby the thermal energy storage unit is modular.

A plate-type heat exchanger includes a plurality of heat transfer plates stacked on top of each other, a flow passage, formed by each space between the plurality of heat transfer plates, through which a fluid flows in a first direction; an inner fin disposed in the flow passage, a first projecting portion provided on an inflow side of each of the heat transfer plates and configured to prevent the fluid from flowing into gaps between both ends of the inner fin in a second direction and both ends of the heat transfer plate in the second direction, and a second projecting portion formed on an outflow side of each of the heat transfer plates and configured to perform positioning in placing the inner fin into the heat transfer plate. The first direction is a direction of flow of the fluid through the flow passage.

Disclosed is a heat exchanger for a thermal management system of an aircraft assembly, the heat exchanger including: a core including a first side with a first core inlet, a second side opposing the first side and includes a first core outlet, the first core inlet is in fluid communication with the first core outlet, a third side having a second core inlet and a fourth side opposing the third side and includes a second core outlet, the second core inlet is in fluid communication with the second core outlet, and a screen wrapped around the core, the screen covering the first core inlet and the first core outlet, and a plurality of rollers disposed between the core and the screen for movably securing the screen to the core, the rollers engaging the screen and movement of at least one of the rollers moves the screen about the core.

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.

An electric arrangement comprising a casing; a heat generating electric component arranged inside the casing; and a heat exchanger comprising a three dimensional lattice cell structure, the three dimensional lattice cell structure being arranged to conduct a dielectric cooling fluid from the casing at an exterior side of the casing for heat exchange with an ambient fluid, and back towards the casing for cooling of the electric component. A panel for a heat exchanger and a heat exchanger comprising a plurality of panels are also provided.

A heat exchanger, includes: a core portion: a first flow path which is provided in the core portion and through which a first fluid flows; and a second flow path which is provided in the core portion and through which a second fluid flows. The first fluid flowing through the first flow path and the second fluid flowing through the second flow path exchange heat through a partition in the core portion. The first flow path includes: a plurality of main flow paths: an introducing chamber; and a discharge chamber. The main flow path includes: an introducing side shape changing section in which a certain flow path is connected in a straight shape to the main flow path adjacent thereto; and a discharge side shape changing section in which the certain flow path is connected in a straight shape to the main flow path adjacent thereto.

A water heater according to the present invention includes: a heating unit that includes a burner provided to cause a combustion reaction from air and fuel, and that is provided to generate heated water by using heat generated by the combustion reaction; and a humidifier unit that generates water steam by evaporating water using a combustion gas generated by the combustion reaction and discharged from the heating unit, and provides the water steam together with the air to the burner.

A heat exchanger includes a header and an annular core fluidly connected to the header. The annular core includes an inner diameter, an outer diameter, first flow channels arranged in a first set of layers, and second flow channels arranged in a second set of layers and interleaved with the first flow channels. Each of the first flow channels includes a first inlet, a first outlet, and a first axial region extending between the first inlet and the first outlet. Each of the second flow channels includes a second inlet, a second outlet, and a second axial region extending between the second inlet and the second outlet.

A heat exchanger including a plurality of tubes, a header, and a plurality of flow voids. The plurality of tubes extends in a first direction through which a first fluid is configured to flow. Each of the plurality of tubes have waves that repeat at regular intervals along the first flow direction and are spaced from one another vertically and laterally in the second direction. The header extends in the first direction and is attached to each of the plurality of tubes. The header is configured to convey the first fluid to each of the plurality of tubes. The plurality of flow voids are formed between the plurality of tubes. The plurality of flow voids extend in a second direction through which a second fluid is configured to flow such that the second fluid is in thermal contact with the plurality of tubes.