Abstract: The present invention provides an improved electrolytic capacitor device and a method of constructing the same. The capacitor includes a central support post that is inserted into an arbor hole in the center of the active element. The present invention provides a capacitor post that has a core material of metal or thermally conductive polymer that has an outer protective layer formed thereon. The outer protective layer is net shape insert molded over the core using a thermally conductive, electrically insulative polymer material that protects the support core from interfering with the electrical operation of the capacitor while increasing the capacitor's ability to transfer waste heat from the active element to the exterior of the device. The outer layer further includes an integrally formed thermal transfer pad that resides adjacent to the outer can of the capacitor when the capacitor post is installed.

Abstract: The present invention provides an improved electrolytic capacitor device and a method of constructing the same. The capacitor includes a central support post that is inserted into an arbor hole in the center of the active element. The present invention provides a capacitor post that has a core material of metal or thermally conductive polymer that has an outer protective layer formed thereon. The outer protective layer is net shape insert molded over the core using a thermally conductive, electrically insulative polymer material that protects the support core from interfering with the electrical operation of the capacitor while increasing the capacitor's ability to transfer waste heat from the active element to the exterior of the device. The outer layer further includes an integrally formed thermal transfer pad that resides adjacent to the outer can of the capacitor when the capacitor post is installed.

Abstract: The present invention discloses a heat pipe construction that includes a heat pipe with phase change media therein with a conductive composition molded about the heat pipe. The thermally conductive composition absorbs or reflects electro magnetic interference waves and prevents their transmission into and through the heat pipe to the electronic components being cooled by the heat pipe.

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: 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 composite heat dissipation assembly having a net shape injection molded thermally conductive elastomeric heat sink and at least one integral heat pipe is provided in the present invention. The molded conformable heat sink is formed from a base elastomeric material that is loaded with thermally conductive filler. The base material is mixed with the filler and net shape molded to form the outer geometry of the assembly. Within the geometry of the part an integral channel is formed that is capable of receiving a heat pipe. The channel is formed to have an opening that is slightly smaller than the outer cross-sectional dimensions of the heat pipe. When the heat pipe is pressed into the channel a portion of the elastomeric material is compressed and the reactionary force of the compressed material firmly presses the elastomer into thermal communication with the outer surface of the heat pipe.

Abstract: A thermally conductive lamp reflector is provided that dissipates heat from a light source within the reflector. The reflector assembly includes a shell having a metallized layer on its surface. The shell is made from a composition including about 30% to about 80% by volume of a base polymer matrix and about 20% to about 70% by volume of a thermally conductive filler material. The reflector has a thermal conductivity of greater than 3 W/m° K and preferably greater than 22 W/m° K. The reflectors can be used in automotive headlamps, flashlights, and other lighting fixtures. A method of forming the lamp reflector is also provided.

Abstract: The present invention relates to thermally conductive, elastomeric pads and methods for manufacturing such pads. The methods involve injection-molding a thermally conductive composition comprising about 30 to 60% by volume of an elastomer polymer matrix and about 25 to 60% by volume of a thermally conductive filler material. The resultant pads have heat transfer properties and can be used as a thermal interface to protect heat-generating electronic devices.

Abstract: This invention relates to a thermally conductive molding composition having a thermal conductivity greater than 3 W/m° K. The composition consists essentially of: a) 30% to 60% of a polymer matrix; b) 25% to 60% of boron nitride; and c) 25% to 60% of alumina. The boron nitride and alumina are dispersed throughout the polymer matrix. The composition can be molded or cast into a variety of articles such as packaging materials for semiconductor devices.

Abstract: The present invention relates to a self-heating container for heating consumable items such as food and beverages. The container assembly includes a star-shaped inner container for holding heating media that produces an exothermic reaction, and an outer container for holding a consumable item such as food and beverages. The inner container includes a thermally conductive polymer composition, and the outer container includes a heat-insulating material. The thermally conductive polymer composition includes a base polymer matrix and filler material.

Abstract: The present invention discloses a method of constructing a heat pipe that includes providing a heat pipe with phase change media therein and injection overmolding the heat pipe with a conductive composition. The thermally conductive composition absorbs or reflects electro magnetic interference waves and prevents their transmission into and through the heat pipe to the electronic components being cooled by the heat pipe.

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: A case for dissipating heat from an electronic device is provided. The case includes an electronic circuit board with a heat generating electronic component installed thereon. A shield is positioned over the electronic component to protect it from electromagnetic interference. The shield includes an aperture through its top surface. A heat transfer conduit is molded into and through the aperture to contact the top surface of the heat generating electronic component. Outer housing, which is made of a thermally conductive material, is placed into contact with the top surface of the heat transfer conduit which extends outside the shield. As a result, heat is dissipated from the electronic component and through the housing of the electronic device via the heat transfer conduit while shielding the electronic component from electromagnetic interference.

Abstract: The electronic connector (10) includes an improved heat dissipating housing for cooling heat generating devices located within the connector (10). The electronic connector (10) of the present invention enables the cost-effective cooling of electronic devices (22, 24) within the connector (10) while realizing superior thermal conductivity and improved electromagnetic shielding. A method of forming an electronic connector (10) that includes the steps of first providing a heat generating electronic component (22, 24) capable of electronically coupling two data devices together having a first port (16a) and a second port (16b). This component (22, 24) is typically mounted or installed into a circuit board (20). An outer housing (12) of moldable thermally conductive polymer material (102, 202, 302, 402) is overmolded around the heat generating electronic component (22, 24) leaving the first port (16a) and the second port (16b) of connector (10) exposed.

Abstract: A case for dissipating heat from an electronic device is provided. The case includes an electronic circuit board with a heat generating electronic component installed thereon. A shield is positioned over the electronic component to protect it from electromagnetic interference. The shield includes an aperture through its top surface. A heat transfer conduit is molded into and through the aperture to contact the top surface of the heat generating electronic component. Outer housing, which is made of a thermally conductive material, is placed into contact with the top surface of the heat transfer conduit which extends outside the shield. As a result, heat is dissipated from the electronic component and through the housing of the electronic device via the heat transfer conduit while shielding the electronic component from electromagnetic interference.

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 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 net-shape moldable U-shaped heat sink assembly formed by injection molding of a thermally conductive polymer composite material is shown. The heat sink assembly includes a base member with a number of integrated fins members thereon. A right upstanding wall extends from a first side of the base member and a left upstanding wall extends from a second side of the base member to form a substantially U-shaped heat sink assembly. To enhance thermal conductivity, fins members may be integrally formed into the base member, right wall and/or left wall during the molding of the heat sink assembly. Also, a flexible metallic substrate or hinges may be embedded within the U-shaped heat sink assembly to permit positioning of the right wall and left wall relative to the base member for custom configuration of the heat sink assembly.

Abstract: A method of manufacturing a net-shape moldable U-shaped heat sink assembly includes injection molding a thermally conductive polymer composite material. The method includes forming a heat sink assembly base member with a number of integrated fins members thereon. A right upstanding wall extends from a first side of the base member and a left upstanding wall extends from a second side of the base member to form a substantially U-shaped heat sink assembly. To enhance thermal conductivity, fins members may be integrally formed into the base member, right wall and/or left wall during the molding of the heat sink assembly. Also, a flexible metallic substrate or hinges may be embedded within the U-shaped heat sink assembly to permit positioning of the right wall and left wall relative to the base member for custom configuration of the heat sink assembly.

Abstract: A highly thermally conductive and high strength net-shape moldable molding composition, with a thermal conductivity above 4 W/m° K and a strength of at least 15 ksi includes a polymer base matrix of, by volume, between 30 and 70 percent. A first highly thermally conductive filler of high modulus PITCH-based carbon, by volume, between 15 and 47 percent is provided in the composition that has a relatively high aspect ratio of at least 10:1. Also in the composition mixture is a second high strength filler of PAN-based carbon, by volume, between 10 and 35 percent that has a relatively high aspect ratio of 10:1 or more. Optionally, a third filler material of thermally conductive material with a relatively low aspect ratio of 5:1 or less may be included in the composition, by volume less than 10 percent, to improve the thermal conductivity and strength of the composition.