At least one embodiment of a power supply includes a printed circuit board formed from a plurality of double-sided laminates and a plurality of thermally conductive, electrically insulating pre-preg sheets interleaved with the plurality of double-sided laminates. Each double-sided laminate illustratively includes an electrically insulating core, a first patterned layer of electrically conductive material arranged on a first side of the electrically insulating core, and a second patterned layer of electrically conductive material arranged on a second side of the electrically insulating core opposite the first side. The printed circuit board illustratively further includes a thermally conductive, electrically insulating additive resin filling spaces between the electrically conductive material in both the first and second patterned layers of each of the plurality of double-sided laminates, such that the electrically conductive material and the additive resin together form planar surfaces that contact the plurality of pre-preg sheets.

The present invention relates to a circuit board structure to which a human body infrared sensor is electrically connected. The circuit board structure comprises a circuit board and a heat insulation structure. The circuit board is provided with an electronic component disposing region, an isolation region and at least one conducting line. The conducting line stretches across the isolation region and the electronic component disposing region. The heat insulation structure is composed of at least one opening which surrounds the periphery of the isolation region. The human body infrared sensor is disposed in the isolation region and electrically connected to the at least one conducting line. Hereby, the change in temperature of the circuit board in the isolation region is moderated to avoid false operations of the human body infrared sensor caused by high temperature or temperature change. The human body infrared sensor is directly attached to the circuit board.

A method of creating thermal boundaries in a substrate is provided. The method includes forming the substrate with first and second sections to be in direct thermal communication with first and second thermal elements, respectively, machining, in the substrate, first and second cavities for defining a third section of the substrate between the first and second sections and disposing a material having a characteristic thermal conductivity that is substantially less than that of the ceramic in the first and second cavities.

A memory system of embodiments includes a container, a first circuit board, a second circuit board, and an optical cable. The container has a hole connecting inside and outside the container. The first circuit board is disposed outside the container and has a first circuit to convert a first electric signal to an optical signal. The second circuit board is disposed inside the container and has a memory device, and a second circuit to convert the optical signal into a second electric signal and storing the second electric signal in the memory device. The optical cable transmits the optical signal from the first circuit board through the hole to the second circuit board.

A self-healing conductive structure includes a conductive layer and a self-healing layer on at least one surface of the conductive layer. The self-healing layer includes a substrate and carbon nanotubes in the insulating matrix, the layer having low viscosity at higher temperatures. When there is a crack in the conductive layer, the self-healing layer flows into the crack, and the carbon nanotubes then in the crack are rearranged under an electric field to repair conductivity. Service life of the conductive structure is improved and signals generated by the conductive structure retain integrity. A method for making the self-healing conductive structure is also provided.

A method of creating thermal boundaries in a substrate is provided. The method includes forming the substrate with first and second sections to be in direct thermal communication with first and second thermal elements, respectively, machining, in the substrate, first and second cavities for defining a third section of the substrate between the first and second sections and disposing a material having a characteristic thermal conductivity that is substantially less than that of the ceramic in the first and second cavities.

A self-healing conductive structure includes a conductive layer and a self-healing layer on at least one surface of the conductive layer. The self-healing layer includes a substrate and carbon nanotubes in the insulating matrix, the layer having low viscosity at higher temperatures. When there is a crack in the conductive layer, the self-healing layer flows into the crack, and the carbon nanotubes then in the crack are rearranged under an electric field to repair conductivity. Service life of the conductive structure is improved and signals generated by the conductive structure retain integrity. A method for making the self-healing conductive structure is also provided.

A heat resistant electronic component is disclosed, comprising an electronic component covered by a layer of ceramic thermal insulation material containing lithium molybdate Li.sub.2MoO.sub.4. A process for manufacturing the heat resistant electronic component comprises obtaining ceramic thermal insulation material containing lithium molybdate Li.sub.2MoO.sub.4 in a mouldable form, optionally mixing the ceramic thermal insulation material with at least one additive, covering an electronic component with the material, shaping the material covering the electronic component into a desired form, and drying the desired form at a temperature of from 20 C. to 120 C.

Printed circuit board (PCB) apparatus comprising an apertured ground plane defining aperture pattern/s in the ground plane, each aperture pattern including apertures which, taken together, surround most but not all of SMT footprint/s and are interspersed with ground plane region/s which provide/s the SMT component with electrical connectivity to area/s of said ground plane other than said SMT footprint, thereby to maintain functionality of the SMT component including electrical connectivity between said SMT footprint and area/s of said ground plane other than said SMT footprint, while also slowing heat dissipation from the SMT footprint by restricting thermal conductivity between said area and said area's vicinity thereby to raise the temperature in the SMT footprint while a SMT component is being soldered thereto, thereby to at least partly prevent improper soldering of the SMT component which may cause the SMT component to subsequently detach from the board.

A method of creating thermal boundaries in a substrate is provided. The method includes forming the substrate with first and second sections to be in direct thermal communication with first and second thermal elements, respectively, machining, in the substrate, first and second cavities for defining a third section of the substrate between the first and second sections and disposing a material having a characteristic thermal conductivity that is substantially less than that of the ceramic in the first and second cavities.