A heat exchanger fixing structure, for two or more heat exchangers bent in multiple layers, includes two or more plates respectively fixed to one ends of the two or more heat exchangers, wherein portions of the two or more plates may overlap each other, and the two or more heat exchangers are connected and fixed to each other by fastening a fastening member to the overlapping portions.

A gas cooler includes a pair of seal plates and a pair of first support ribs. The individual seal plate has a stepped surface which extends in a direction that a cooling portion is inserted into a casing. The individual first support rib supports the stepped surface. With the configuration where the stepped surface is supported by the first support rib, the inside of the casing is partitioned into an upstream-side space communicated with an introducing port and a downstream-side space communicated with a discharging port.

A frameless cooling module includes a first and a second shroud panel arranged at opposing sides of the module and extending from the front of the module to the back of the module. At least one L-shaped stiffener bracket extends between the panels at an intermediate location along both the height direction and the depth direction of the module. One or more heat exchangers is arranged within the cooling module between the L-shaped stiffener bracket and the front of the module, and is at least partially secured within the cooling module by being mounted to the L-shaped stiffener bracket.

A heat exchanger arrangement (2) comprises at least one heat exchanger (4) including at least one substantially horizontally oriented manifold (6a, 6b) forming an upper side of the at least one heat exchanger (4), the at least one manifold (6a, 6b) having lateral end portions (8); and a support structure (10) including a main portion comprising, at least partially, a metallic material, and manifold support portions (14) associated to respective lateral end portions (8) of the at least one manifold (6a, 6b). The manifold support portions (14) are made at least partially from a non-metallic material and configured to receive the lateral end portions (8) of the at least one manifold (6a, 6b) for preventing the at least one manifold (6a, 6b) from contacting any metallic portions of the support structure (10).

A heat exchanger cabinet includes a base pallet. A heat exchanger base bracket of a selected fixed height or of an adjustable height bracket provides a support for a bottom of a heat exchanger, such that regardless of a height the heat exchanger, and within a range of different heat exchanger heights, a plurality of top mounted fluid inlets and outlets of the heat exchanger are disposed at about a same height above the base pallet. A set of heat exchanger base brackets, a stackable heat exchanger base bracket, a heat shield for a heat exchanger cabinet, and a heat exchanger cabinet for a vertically mounted heat exchanger are also described.

A heat sink includes: a container in which a cavity is formed, the container having a first principal surface and a second principal surface; a working fluid encapsulated in the cavity, and a steam flow path defined in the cavity, in which the container has a flat portion and a protruding part projecting from the flat portion, an inner space of the protruding part of the container is in communication with an inner space of the flat portion to form the cavity, the protruding part of the container includes a heat receiver that is to be thermally connected with a heating element that is a cooling target, and the flat portion of the container has an intermediate portion region continuous from the protruding part and a heat radiator region more distant from the protruding part than the intermediate portion region and thermally connected with a heat radiating fin.

The present teachings provide for a bracket for a heat exchanger assembly including a first heat exchanger, a second heat exchanger, and a third heat exchanger. The bracket can include a first landing, a second landing, a bridge member and a retention member. The first landing can be configured to be fixedly coupled to the first heat exchanger. The second landing can define a first aperture that can be configured to receive a first fastener through the second landing. The bridge member can be fixedly coupled to the first and second landings. The retention member can be fixedly coupled to the second landing. The retention member and the second landing can define a slot that can be adapted to receive a portion of the second heat exchanger.

The present disclosure relates to heat exchanger for a power generation system and related methods that use supercritical fluids, and in particular to a heat exchanger configured to minimize axial forces during operation.

The present disclosure relates to heat exchanger for a power generation system and related methods that use supercritical fluids, and in particular to a heat exchanger configured to minimize axial forces during operation.

An external frame for a heat exchanger, the external frame being for holding a heat exchanger core; wherein the external frame is a single integrated structure including: inlet and outlet couplings for connection to a first fluid circuit for supply and return of a first fluid to the heat exchanger core; a first tank at a first end of the external frame for fluid communication with a first end of the heat exchanger core; a second tank at a second end of the external frame for fluid communication with a second end of the heat exchanger core; and a gallery extending along the external frame between the first tank and the second tank providing fluid communication between the first tank and the second tank; wherein the external frame is arranged to be sealed to the heat exchanger core so that the first fluid flows from the inlet, through the heat exchanger core and the tanks, and to the outlet.