Abstract: A net-shape molded heat transfer component is provided which includes a thermally conductive core and a metallic coating for reflection of electromagnetic interference and radio frequency waves. The heat transfer component is formed by net-shape molding a core body from a thermally conductive composition, such as a polymer composition, and applying a metallic coating. The molded heat transfer part is freely convecting through the part, which makes it more efficient and has an optimal thermal configuration. Additionally, the part is shielded from electromagnetic interference and radio frequency waves, thus preventing the transfer of same into the circuitry housed by the part. In addition, the coating also seals the conductive polymer core against moisture infiltration, making the part well suited for telecommunications applications in potentially harsh environments.

Abstract: A process is disclosed for brazing plate/plate and plate/fin multi-channeled structures using an amorphous brazing foil as a brazing filler metal between the parts in order to form uniform joints having optimal dimensions, shape and strength. The parts are assembled in an unconstrained stack, and a controlled load is applied to the top of the stack. The stack is then heated to a temperature at which the interlayer melts and reacts with the base metal to form the joints. The stack is cooled resulting in a brazed structure having the desired characteristics, wherein the brazed joints are optimally formed and the strength of the structure is equal to the underlying strength of the base metal.

Abstract: A method for preparing a heat exchanger, comprising forming a moisture-permeable film having an air-impermeable function on a single side of a plate-shaped porous member to provide a gas-impermeable member for heat exchange, bonding a spacer corrugated for forming a fluid passage to a side of the gas-impermeable member with the moisture-permeable film formed thereon to provide a plurality of heat exchanger constituent elements, and layering the heat exchanger constituent elements so that the spacer in each of the heat exchanger constituent elements forms a fluid passage in each layer.

Abstract: A hydrophilic modification method comprising

Abstract: A heat exchanger has a plurality of fluidically parallel first layers which define first heat exchanger ducts through which a first medium is capable of flowing, and in each case has a second layer between the two first layers. The respective second layer is in thermal contact with the two adjacent first layers and defines at least one second heat exchanger duct through which a second medium is capable of flowing in parallel. The respective second layer comprises two fluidically parallel layer plies. A controllable supply of the second medium to the one and/or the other layer ply in each case is provided. Such a heat exchanger can be used, in particular, as an evaporator with an integrated starting and main evaporator part, and particularly as an evaporator in a reforming plant of a fuel-cell vehicle.

Abstract: The present invention relates to a system for managing the heat from a heat source like an electronic component. More particularly, the present invention relates to a system effective for dissipating the heat generated by an electronic component using a heat sink formed from a compressed, comminuted particles of resin-impregnated flexible graphite mat or sheet.

Abstract: A heat sink is manufactured by forming a fin 2 for dissipating heat by separating a length of material from a substrate 1 while leaving the proximal end attached to the substrate 1. The fins are cut from the substrate by stamping process using the stamping single or progressive die tooling cutting the substrate 1 along dotted line 16. The heat sink is a unitary construction, with the fins 2 being integrally formed with the substrate 1.

Abstract: A heat sink assembly for removing heat from an object having an outer surface includes a main body with an object receiving seat. A pair of flexible securing tabs are connected to the free edge of the open end of the main body which emanate into the open end of the main body. A heat dissipation members emanate from the outer surface of the main body to assist in dissipating the heat received by the main body from the heat generating object. The main body, the pair of flexible securing tabs and heat dissipating members are integrally formed with one another of a thermally conductive elastic or elastomeric material. An object to be cooled is inserted into the object receiving seat of the main body and retained in the seat and in communication with the inner surfaces of the main body by the pair of flexible securing tabs.

Abstract: To make stress corrosion cracking caused by precipitation of a &bgr; layer (Mg2Al3) in a welding part (5) or in the periphery of the welding part (5) hard to occur. An apparatus body (1) and a header (3) formed of an aluminum alloy with precipitation of magnesium suppressed by standardized heat treatment are assembled and welded, and natural gas containing mercury is subjected to heat exchanging. There are provided with backing metal (4) disposed on the back of the inner wall surface of one header (3) prior to standardized heat treatment and placed in contact with the other apparatus body (1) at the time of assembling and welding, a welding part (5) formed by being assembled and welded using first welding metal containing magnesium at percent content not less than 2.

Abstract: The present invention relates to a system for managing the heat from a heat source like an electronic component. More particularly, the present invention relates to a system effective for dissipating the heat generated by an electronic component using a thermal management system that includes a thermal interface formed from a flexible graphite sheet and/or a heat sink formed from a graphite article.

Abstract: A heat exchanger and a heat exchanger core are disclosed. The heat exchanger core is formed from a strip of synthetic resin molded into multiple panels which are accordion folded to form the heat exchanger core. One embodiment is a counterflow core in which sides of each panel parallel to the longitudinal axis of the strip are divided to form a closed portion and an open portion. The opposite longitudinal sides are similarly formed but the portions are reversed. The sides of each panel perpendicular to the longitudinal axis of the strip are closed either by a hinge formed in the strip or by panel borders abutting each other. A second embodiment discloses a strip also formed into multiple panels and accordion folded. However, every second hinge has an opening so that when folded, a cross flow core is created. Both cores are mated with appropriately designed molded plastic housings to form effective but simple and economical heat exchangers.

Abstract: A process is presented for forming an anisotropic graphite article, comprising forming a laminate comprising a plurality of flexible graphite sheets which comprise graphene layers; and directionally aligning the graphene layers of the laminate.

Abstract: A construction is provided for a finned heat sink constructed from a plurality of components separately formed from graphite materials. The components include a base and a plurality of fins. In one embodiment, the base is constructed from a first graphite material, and a plurality of elongated fins are constructed from a second graphite material, which may be the same material as the first graphite material. The fins each extend at least partially into the base, and have a length extending away from the base parallel to each other. The graphite material of the fins includes graphene layers aligned in planes parallel to the length of the fins. Two constructions are provided for the base. In one construction the base includes graphene layers aligned in planes parallel to the length of the fins. In another construction the base includes graphene layers aligned in planes perpendicular to the length of the fins.

Abstract: A process is presented for forming an anisotropic heat spreader or heat pipe, comprising forming a laminate comprising a plurality of flexible graphite sheets which comprise graphene layers; and directionally aligning the graphene layers of the laminate.

Abstract: In a brazed condenser for an air conditioner, such as a motor vehicle air conditioner, a collecting tube connected with a collector is a prefabricated as a one-piece tube which is connected by tack weld seams with the collector before brazing the collecting tube and the collector together.

Abstract: A process is disclosed for brazing plate/plate and plate/fin multi-channeled structures using an amorphous brazing foil as a brazing filler met between the parts in order to form uniform joints having optimal dimensions, shape and strength. The parts are assembled in an unconstrained stack, and a controlled load is applied to the top of the stack. The stack is then heated to a temperature at which the interlayer melts and reacts with the base metal to form the joints. The stack is cooled resulting in a brazed structure having the desired characteristics, wherein the strength of the structure is equal to the underlying strength of the base metal.

Abstract: Strip or drawn tube for the manufacture of a brazed heat exchanger, formed from an aluminum alloy containing Si, Cu and Mn, with optional amounts of Mg, Fe, Zn and Ti, where Fe≦Si, and Cu+Mg>0.4. In the form of a strip, the alloy may be coated on one or both surfaces with an aluminum brazing alloy.

Abstract: This invention is a process for making improved micro-multiport tubing for use in heat exchangers. A multivoid heat exchanger tube is extruded from aluminum alloy billet. The alloy is a composition of cooperative elements which act with the aluminum to prevent recrystallization and grain growth which result in the necessary strength and duality of characteristics in the tubes. The composition of the alloy that is added to aluminum is some or all of the following: silicon, iron, copper, magnesium, manganese, zinc and titanium. The cold work during processing of the heat exchanger is limited to further retain the small grains.

Abstract: The invention is a very flexible heat pipe which is constructed of multiple layers of material laminated into the final structure. The center of the symmetrical structure is a coarse screen which creates a vapor space. The layers on either side of the screen are copper felt pads, and the outer casing is two layers of metal foil and a layer of polypropylene. The heat pipe constructed in this manner is so a flexible that when one outside surface is covered with adhesive, the heat pipe can essentially be used as tape or a stick-on heat transfer surface which conforms to a body being cooled.

Abstract: An aluminum alloy containing (in wt. %): 0.2-0.5 Fe; 0.7-1.2 Si; 1.2-1.6 Mn; up to 0.3 Mg; up to 0.5 Cu; up to 0.2 Zn; up to 0.1 Ti is used to make the fins of heat exchangers particularly car radiators. The finstock has high post braze strength and thermal conductivity, and has a sufficiently electronegative potential as to be capable of acting as a sacrificial anode for the heat exchanger tubes. By virtue of the absence of Sn, In, and Cr, these heat exchangers can be scrapped and melted for re-use.

Abstract: An actively cooled, heat-dissipating module is presented for dissipating thermal energy from a heat producing integrated circuit device. The heat-dissipating module features a tungsten carbide body having high-density fins and a base with an interfacial surface adapted for attachment to an IC device. The base may also be bonded at high-pressure and high-temperature to a sintered polycrystalline diamond buffer element that, in turn, features a metalized interfacial surface suitable for attachment to the device. The high-density fins present a combined surface area at least 20 times greater than the surface area of the interfacial surface of the buffer element or the base of the heat-dissipating module. The tungsten carbide fins are capable of withstanding high flow and high velocity fluid environments. The high surface area of the fins optimizes the convective transfer of thermal energy from the fins to the high flow of cooling fluid.

Abstract: The heat exchanger of the present invention is capable of easily adjusting temperature of a machining liquid, e.g., slurry, etching liquid. The heat exchanger of the present invention, which adjusts temperature of the machining liquid, comprises a ceramic heat exchanging tube, which is made by baking silicon carbide (SiC).

Abstract: A heat spreader, comprised of a plurality of carbon fibers oriented in a plurality of directions, with a carbon or metal matrix material dispersed about the fibers, is described. The carbon fibers facilitate the spreading of heat away from the smaller semiconductor device and up to a larger heat removal device, such as a heat sink.

Abstract: In order to provide a cooling/heating apparatus for a semiconductor processing liquid being highly resistant to corrosive chemicals and free from elution of harmful impurities, a heat exchanging substrate 3 is formed by heat-depositing a fluorine-contained resin sheet 3B to a processing liquid contact surface of a graphite substrate 3A.

Abstract: A motor vehicle heat exchanger has a bundle (10) formed solely from flexible tubes (12) made of plastics, as well as two end blocks (22, 24) joining these tubes. The heat exchanger further has at least one spacer (50) arranged at a chosen location between the end blocks (22, 24) and including apertures for the tubes to pass in order to provide support for the tubes (12) with a chosen spacing or pitch.

Abstract: Oxidation protection of a titanium heat exchanger is provided by a titanium aluminide or solgel coating. The coating protects bare titanium and brazed surfaces of the heat exchanger.

Abstract: In order to provide a cooling/heating apparatus for a semiconductor processing liquid being highly resistant to corrosive chemicals and free from elution of harmful impurities, a heat exchanging substrate 3 is formed by heat-depositing a fluorine-contained resin sheet 3B to a processing liquid contact surface of a graphite substrate 3A.

Abstract: An aluminum alloy composite material includes a higher strength aluminum alloy core material layer and at least one cladding aluminum alloy material layer having a higher electrical conductivity than the core material. The cladding layer is positioned adjacent to the core and the composite is adapted for particular application in heat exchangers where brazing is conducted under controlled atmospheres with special flux materials. The core material has an electrical conductivity less than 50% IACS and the cladding layer has an electrical conductivity greater than 50% IACS. The cladding layer can be on one or both surfaces of the core layer. The thickness of the cladding layer can range between about 2.5 and 40% of the overall composite thickness depending on whether one or more cladding layers are employed. The cladding layer also has a corrosion potential more negative than the core layer for enhanced corrosion resistance.

Abstract: Heat sinks are provided that achieve very high convective heat transfer surface per unit volume. These heat sinks comprise a spreader plate, at least two fins and at least one porous reticulated foam block that fills the space between the fins.

Abstract: The present invention relates to a heat exchanger applied for an IC production line or the like, wherein, on plural independent tube holding holes 20 formed on holding plates 20, ends of resin tubes are arranged, and a predetermined length range &agr; of the each resin tube is integrally fused into the each holding plate inside the tube holding holes. Each fusing portion for fusing the plural resin tubes into the holding plates has a non-contacted congestion structure wherein the resin tubes are not mutually contacted, thereby increasing reliability on connecting the fusing portion, and meanwhile, facilitating miniaturization of the heat exchanger by increasing heat-exchange efficiency and elements such as the resin tubes and the holding plates may be made of a fluororesin.

Abstract: The increase of temperature in heat sensitive devices during heat generating conditions is prevented through the absorption of heat, by providing Boric acid in an amount sufficient to effect the required heat absorption. Where the heat generating conditions are generated by a heat generator, separate and distinct from the heat sensitive device, the Boric acid is supported in a position between the heat sensitive device and the heat generator. Where the heat sensitive device is itself the heat generator, the Boric acid is contacted to the heat sensitive device either directly or indirectly.

Abstract: The increase of temperature in heat sensitive devices during heat generating conditions is prevented through the absorption of heat, by providing a salt of an organic acid such as lithium formate and its hydrates, beryllium formate and its hydrates, sodium formate and its hydrates, magnesium formate and its hydrates, aluminum formate and its hydrates, potassium formate and its hydrates, calcium formate and its hydrates, ammonium formate and its hydrates, lithium acetate and its hydrates, beryllium acetate and its hydrates, sodium acetate and its hydrates, magnesium acetate and its hydrates, aluminum acetate and its hydrates, potassium acetate and its hydrates, calcium acetate and its hydrates, ammonium acetate and its hydrates, lithium propionate and its hydrates, beryllium propionate and its hydrates, sodium propionate and its hydrates, magnesium propionate and its hydrates, aluminum propionate and its hydrates, potassium propionate and its hydrates, calcium propionate and its hydrates, ammonium propionate a

Abstract: An aluminum alloy clad material for heat exchangers exhibiting superior strength after brazing and excellent corrosion resistance is provided. The aluminum alloy clad material comprises a sacrificial anode material which is clad on one side of a core material, wherein the core material comprises an aluminum alloy comprising 0.3-2.0% of Mn, 0.25-1.0% of Cu, 0.3-1.1% of Si, and 0.05-0.35% of Ti with the remaining portion consisting of aluminum and impurities, the sacrificial anode material comprises an aluminum alloy comprising 1.5-8% of Zn, 0.01-0.8% of Si, and 0.01-0.3% of Fe with the remaining portion consisting of aluminum and impurities, and the total number of particles of Si compounds and Fe compounds with a particle diameter (circle equivalent diameter) of 1 &mgr;m or more present in the sacrificial anode material matrix is 2×104 or less per 1 mm2. The clad material is suitably used as a tube material or header plate material for automotive heat exchangers such as a radiator or heater core.

Abstract: The increase of temperature in heat sensitive devices during heat generating conditions is prevented through the absorption of heat, by providing an aldehyde such as formaldehyde (methanol), acetaldehyde (ethanal), propionaldehyde (propanal), n-butyraldehyde (butanal), benzaldehyde, p-Nitrobenzaldehyde, p-tolualdehyde, salicylaldehyde (ortho-hydroxybenzaldehyde), phenylacetalaldehyde (phenylethanal), alpha-methylvaleraldehyde (2-methylpentanal), beta-methyvaleraldehyde (3-methylpentanal), isocaproaldehyde (4-methylpentanal), paraformaldehyde, trioxane, dioxane, paraldehydeand the mixtures thereof, in an amount sufficient to effect the required heat absorption. Where the heat generating conditions are generated by a heat generator, separate and distinct from the heat sensitive device, the aldehyde is supported in a position between the heat sensitive device and the heat generator.

Abstract: The increase of temperature in heat sensitive devices during heat generating conditions is prevented through the absorption of heat, by providing a hydrated salt such as Lithium Chloride, Magnesium Chloride, Magnesium Sulfate, Sodium Sulfate, Aluminum Oxide, Aluminum Sulfate, Aluminum Fluoride, Aluminum Nitrate, Lithium Nitrate, Sodium Borate, Beryllium Sulfate, Sodium Phosphate, Calcium Chloride, Zinc Sulfate, Aluminum Chloride, Zinc Chloride and the mixtures thereof, in an amount sufficient to effect the required heat absorption. Where the heat generating conditions are generated by a heat generator, separate and distinct from the heat sensitive device, the hydrated salt is supported in a position between the heat sensitive device and the heat generator. Where the heat sensitive device is itself the heat generator, the hydrated salt is contacted to the heat sensitive device either directly or indirectly.

Abstract: In a capillary evaporator for use in a capillary pumped loop, in which capillary action in a porous wick 7 causes cold liquid to be drawn across the wick and vaporized by a heat input structure 6 and in particular fin 8 of that structure so that the vapour passes around a loop and rejects heat at a condenser in order to cool equipment in the vicinity of the evaporator, the vapour generated in the wick 7 from the liquid/vapor interface (meniscus) 11 is subject to a lower pressure drop than hitherto by virtue of a spacer 14 of greater permeability and thermal conductivity than the wick 7 without the necessity for the meniscus 11 to recede from the fin 8 which would cause an undesirable temperature drop of the meniscus, thereby improving the capacity of the evaporator to pump liquid/vapor around the loop and thus transport heat.

Abstract: The increase of temperature in heat sensitive devices during heat generating conditions is prevented through the absorption of heat, by providing an organic acid such as formic acid, acetic acid, propanoic acid, butyric acid and the mixtures thereof, in an amount sufficient to effect the required heat absorption. Where the heat generating conditions are generated by a heat generator, separate and distinct from the heat sensitive device, the organic acid is supported in a position between the heat sensitive device and the heat generator. Where the heat sensitive device is itself the heat generator, the organic acid is contacted to the heat sensitive device either directly or indirectly.

Abstract: The increase of temperature in heat sensitive devices during heat generating conditions is prevented through the absorption of heat, by providing a bicarbonate salt, such as Lithium Bicarbonate, Sodium Bicarbonate, Potassium Bicarbonate, Magnesium Bicarbonate, Calcium Bicarbonate, Beryllium Bicarbonate, Aluminum Bicarbonate, Ammonium Bicarbonate and the mixtures thereof, in an amount sufficient to effect the required best absorption. Where the heat generating conditions are generated by a heat generator, separate and distinct from the heat sensitive device, the bicarbonate salt is supported in a position between the heat sensitive device and the heat generator. Where the heat sensitive device is itself the heat generator, the bicarbonate salt is contacted to the heat sensitive device either directly or indirectly.

Abstract: The increase of temperature in heat sensitive devices during heat generating conditions is prevented through the absorption of heat, by providing a carbonate salt, such as Lithium Carbonate and its hydrates, Sodium Carbonate and its hydrates, Potassium Carbonate and its hydrates, Magnesium Carbonate and its hydrates, Calcium Carbonate and its hydrates, Beryllium Carbonate and its hydrates, Aluminum Carbonate and its hydrates, and the mixtures thereof, in an amount sufficient to effect the required heat absorption. Where the heat generating conditions are generated by a heat generator, separate and distinct from the heat sensitive device, the carbonate salt is supported in a position between the heat sensitive device and the heat generator. Where the heat sensitive device is itself the heat generator, the carbonate salt is contacted to the heat sensitive device either directly or indirectly.

Abstract: A honeycomb regenerator is constructed by (a) honeycomb structural bodies arranged in a high temperature portion, in which a temperature is over 1250° C. during a normal operation, made of aluminum-titanate or a combination of aluminum-titanate and mullite, and (b) honeycomb structural bodies arranged in a low temperature portion, made of cordierite and/or mullite, or by (a) honeycomb structural bodies arranged in a high temperature portion, to which an exhaust gas having a high temperature is contacted, made of aluminum-titanate or a combination of aluminum-titanate and mullite, (b) honeycomb structural bodies arranged in a middle temperature portion made of alumina and (c) honeycomb structural bodies arranged in a low temperature portion made of one material or a combination of materials selected from a group of cordierite, mullite and a porcelain.

Abstract: A heat exchange apparatus is provided which is formed from at least one multilayer presealed element and at least one monolayer element that are insert molded together. The heat exchange apparatus is provided with an inlet and an outlet for a process fluid and at least one inlet and at least one outlet for a heat exchange fluid. The sealing configuration of the presealed elements and the seal provided by the insert molding effect a seal configuration that causes heat to be transferred between the process fluid and the heat exchange fluid while preventing mass transfer between the two fluids.

Abstract: A superconducting heat transfer medium that has three basic layers, the first layer being various combinations of sodium, beryllium, a metal such as manganese or aluminum, calcium, boron and dichromate radical; the second layer formed over the first layer and being various combinations of cobalt, manganese, beryllium, strontium, rhodium, copper, .beta.-titanium, potassium, boron, calcium, a metal such as manganese or aluminum and the dichromate radical; and the third layer formed over the second layer and being various combinations of rhodium oxide, potassium dichromate, radium oxide, sodium dichromate, silver dichromate, monocrystalline silicon, beryllium oxide, strontium chromate, boron oxide, .beta.-titanium and a metal dichromate, such as manganese dichromate or aluminum dichromate.

Abstract: A pressurized fluid circulating assembly includes a body made of non-metallic, brittle material. At least two apertures formed by internal threads are disposed in the body. First coupling members each include a first externally threaded male portion that can engage the threads of one of the apertures, a second internally threaded female portion and a head with multiple flats. Second coupling members each have an externally threaded male portion that can engage the second threaded portion of one of the first coupling members. A movement-inhibiting member is disposed at a fixed position near at least one flat of each of two of the first coupling members to prevent their rotation. A device may employ a movement-inhibiting member having a size and shape so as to be adapted to be received at a fixed position near at least one flat of each of two of the first coupling members when threaded into engagement with the apertures, thereby preventing rotation of the first coupling members.

Abstract: A structure for supporting and at least transferring heat energy away from at least a first heat source interconnected thereto is disclosed. In one embodiment, the structure includes a deck member having a plurality of layers of thermally conductive fibers packed within a matrix material. Fibers of at least a first layer are orientable to transfer heat energy toward at least a first sidewall of the deck member, and fibers of at least a second layer are orientable about .+-.45.degree. relative to the fibers of the first layer to enhance the structural strength of the deck member. In another embodiment, fibers of at least a first layer of thermally conductive fibers of the deck member are orientable to transfer heat energy from a first heat source to a second, cooler heat source, both of which are interconnectable to the deck member, such that the first and second heat sources operate at substantially uniform temperatures.

Abstract: This heat recovering apparatus for a cogeneration system with an engine comprises a turbocharger driven by an exhaust gas, an energy recovering turbine provided on the downstream side of the turbocharger, and a heat exchanger provided on the downstream side of the energy recovering turbine. The energy recovering turbine comprises a gas turbine driven by an exhaust gas, and a steam turbine driven by steam occurring in the heat exchanger. The heat exchanger comprises a casing joined to an exhaust gas passage, oxidation resisting ceramic pipes, in which the water and steam flow, provided in the casing, and oxidation resisting ceramic porous members, through which an exhaust gas can pass, provided in the portions of the interior of the casing which are on the outer sides of the ceramic pipes.

Abstract: An opposed flow heat exchanger comprising partitions including a corrugated portion for forming passages in a wavefront direction, and flat portions for taking in or out air flows from a predetermined direction at opposite ends of the corrugated portion in the wavefront direction; and flat shape holding plates having a length in a direction of the passages which is not longer than a length of the partitions; wherein the partitions and the shape holding plates are alternately layered so that the corrugated portion of each of the partitions and the shape holding plates contact together, and the flat portion of each of the partitions faces to the flat portion of a partition adjacent thereto, thereby independently forming the passages through the partitions.

Abstract: An aluminum alloy article consisting essentially of controlled amounts of iron, silicon, copper, manganese, magnesium, titanium, zinc, zirconium and free machining elements with the balance being aluminum and incidental impurities is adapted for use as a connector block in a heat exchanger assembly. The connector block has a connector block body with at least one machined portion therein and is configured to be brazed to a portion of the heat exchanger, particularly the heat, exchanger header. The aluminum alloy combines the properties of machinability, corrosion resistance, strength and brazeability. A connector block made from the aluminum alloy can be machined to the right configuration and can be brazed to the heat exchanger header to form a high quality brazed joint. In addition, the connector block can withstand the corrosive environment associated with the heat exchanger and has the necessary mechanical properties to interface with other heat exchanger components.

Abstract: The present invention relates to an Al alloy brazing sheet for use in vacuum brazing, which is applied to manufacture a heat exchanger having a tank portion and a refrigerant passage respectively formed by bonding press-formed brazing sheets together by means of vacuum brazing. The brazing sheet includes an Al alloy core material having a composition consisting of 0.5 to 2.0 mass % (hereinafter abbreviated simply as %) of Mn, 0.1 to 1.0% of Cu, 0.05 to 0.5% of Mg and 0 to 0.3%. of Ti, with the remainder being Al and inevitable impurities. An Al--Si--Mg alloy brazing filler metal or an alloy brazing filler metal prepared by further adding 0.05 to 1.0% of Sn to the Al--Si--Mg alloy brazing filler metal, is clad on both surfaces of the sheet to a thickness of 5 to 20% the total sheet thickness. An intermediate layer consisting of an Al alloy having a composition consisting of 0.5 to 2.0% of Mn, 0.05 to 0.5% of Mg and 0 to 0.

Abstract: A bilayer of polymer film arranged in a manner to create respective flow paths for a first and second gaseous or liquid fluid, wherein the ratio of the surface area of polymer film adapted to contact and thereby isolate both fluids to the total matrix volume is in excess of 700 m.sup.2 /m.sup.3, processes for the preparation thereof, heat exchangers comprising such bilayers and uses thereof.

Abstract: The coolant plate component of a fuel cell assembly is formed from a plate made from graphite particles that are bonded together by a fluorocarbon polymer binder and which encapsulate a serpentine coolant circulation tube. The coolant plate component is non-porous. The graphite particles are preferably flakes which pack together very tightly, and require only a minor amount of the polymer binder to form a solid plate. The plate will provide enhanced heat transfer, will conduct electrons, and will block electrolyte migration from cell to cell in a fuel cell stack due to its construction. The composition of the plate is graded so as to provide a varied coefficient of thermal expansion as measured through the thickness of the plate so as to reduce thermal stresses imposed on the fuel cell stack. The coolant circulation tube has a roughened outer surface which enhances adhesion of the encapsulating graphite flake/binder mixture without inhibiting heat transfer.