Process for producing an element comprising a multilayer architecture, the layers of which comprise primary channels on their upper faces, said process comprising the following successive steps: (a) producing secondary channels on the lower faces of each layer, each secondary channel being intended to be facing a primary channel of the neighboring lower layer within the architecture, (b) depositing a coating that protects against oxidation at a temperature of between 500 C. and 1000 C. and against corrosion over all of the lower and upper surfaces of the layers, (c) sanding or mechanical cleaning of the surfaces intended to be assembled, and (d) assembling via superposition of the various layers so that each secondary channel of a lower face of an upper layer is facing and is centered on a primary channel of the neighboring lower layer,
the width of each secondary channel being greater than the width of the primary channel which it is facing within the architecture.

The present invention relates to an novel method of producing heat exchangers having at least two fluid circuits each comprising channels, the method employing diffusion bonding achieved using the hot isostatic pressing (HIP) technique, and to a heat exchanger obtained using this method.

A process for building a high-performance liquid flow-through plate is provided and includes providing a substrate formed of metal matrix composite (MMC) material, metallizing a surface of the substrate to reform the surface into a metallized surface, placing a braze foil on the metallized surface and executing a high-temperature and high-pressure bake whereby material of the braze foil diffuses into the metallized surface.

A micro-channeled panel heat exchange system is disclosed. An example embodiment includes: one or more micro-channeled panels, each micro-channeled panel having micro-channels fabricated internally within each micro-channeled panel for transfer of a working fluid, each of the one or more micro-channeled panels having a cover layer diffusion bonded or brazed to the micro-channels, each of the one or more micro-channeled panels having a thickness of no more than two millimeters, each of the one or more micro-channeled panels being twisted into a non-orthogonal shape; and one or more manifolds coupled to the one or more micro-channeled panels to circulate the working fluid through the micro-channels within each micro-channeled panel.

A method for fabrication of heat exchangers with at least two fluid circuits each one comprising channels based on grooved plates includes assembling elementary exchanger modules, each of the elementary exchanger modules having been produced by diffusion bonding of grooved plates.

A nuclear reactor comprising a vessel and a micro-channel heat exchanger is disclosed. The vessel houses coolant defining a maximum level within the vessel, and the micro-channel heat exchanger is partially submerged below the maximum level. The micro-channel heat exchanger comprises a core, a plurality of primary channels, and a plurality of secondary channels. The core comprises a top face, a bottom face disposed opposite the top face, a first side face extending between the top face and the bottom face, and a second side face disposed opposite the first side face. The plurality of primary channels extends through the core from a primary inlet of the first side face to a primary outlet of the second side face. The plurality of secondary channels extends through the core among the plurality of primary channels from a secondary inlet of the top face to a secondary outlet of the top face.

A plate-type heat exchanger may include a housing. The housing may include a plurality of rectangular plate-like components that are box-like components each having the same shape and having a standing wall section along a peripheral edge. One of the box-like components may be layered on another components reversed in the horizontal direction to form a layered structure having an upper layer component and a lower layer component such that an upper portion of a standing wall section of the lower layer component of the layered structure is fit into a lower portion of a standing wall section of the upper layer component of the layered structure. The angle () of the standing wall sections may be 30, and at least a portion of a contact region between the upper portion and the lower portion may be joined by solid phase diffusion bonding.

A heat exchanger for a nuclear reactor is provided. The heat exchanger comprises a first layer for flowing a first process fluid and a second layer for flowing a second process fluid. The first layer is comprised of a first material and the second layer is comprised of a second material differing in composition from the first material. The first layer and the second layer are stacked on each other in a core of the heat exchanger and the first layer and the second layer are bonded to each other. A heat exchanger for a nuclear reactor and a method for producing a heat exchanger are also provided.

The disclosure includes a heat exchanging apparatus, comprising a heat exchanger plate comprising a plurality of flow passages, and wherein each flow passage comprises at least one surface feature configured to change the flow characteristics of a linear flow along an axis of flow for the flow passage. The disclosure further includes a method of constructing a heat exchanger, comprising using additive manufacturing to form a first plate having a plurality of flow passages, wherein each of the flow passages has one or more integrally formed surface features, wherein the integrally formed surface features are configured to change the flow characteristics of a fluid flowed linearly along an axis of flow for the flow passage.

A heat exchanger is provided and includes parting sheets flat along a first axis and curved along a second axis perpendicular to the first axis, a fin sheet interposed between the parting sheets and corrugated along the first axis to form fins that are curved along the second axis and diffusion bonds formed along an entire length of a fin to diffusion bond the entire length of the fin to the parting sheets.