A flexible laminated sheet manufacturing method includes thermocompression-bonding an insulation film formed of a liquid crystal polymer onto a metal foil between endless belts to form a flexible laminated sheet. The thermocompression bonding includes heating the flexible laminated sheet so that the maximum temperature of the sheet is in the range from a temperature that is 45° C. lower than the melting point of the liquid crystal polymer to a temperature that is 5° C. lower than the melting point. The thermocompression bonding also includes slowly cooling the flexible laminated sheet so that an exit temperature, which is a temperature of the sheet when transferred out of the endless belts, is in the range from a temperature that is 235° C. lower than the melting point of the liquid crystal polymer to a temperature that is 100° C. lower than the melting point.

A method for making a conductive polymer for electromagnetic shielding purposes includes steps of mixing liquid crystal monomers, a silver complex, an initiator, and a catalytic agent in certain proportions by weight to form a mixture. A solvent is added into the mixture, the mixture and the solvent being in a ratio from 3:17 to 1:3 by weight. The mixture is heated to undergo an atom transfer radical polymerization.

A method of lamination of dielectric circuit materials is provided. The method includes preparing first and second circuit layers of dielectric materials, stacking the first and second circuit layers with circuit trace elements interposed between the first and second circuit layers and ultrasonically welding the second circuit layer onto the first circuit layer around the circuit trace elements.

One aspect of the present invention is a method for manufacturing an electronic component, the method including: a first step of applying a metal paste containing metal particles onto a polymer compact in a prescribed pattern to form a metal paste layer; a second step of sintering the metal particles to form metal wiring; a third step of applying a solder paste containing solder particles and a resin component onto the metal wiring to form a solder paste layer; a fourth step of disposing an electronic element on the solder paste layer; and a fifth step of heating the solder paste layer so as to form a solder layer bonding the metal wiring and the electronic element, and so as to form a resin layer covering at least a portion of the solder layer.

A process for forming a graphene circuit pattern on an object is described. A graphene layer is grown on a metal foil. A bonding layer is formed on a protective film and a surface of the bonding layer is roughened. The graphene layer is transferred onto the roughened surface of the bonding layer. The protective film is removed and the bonding layer is laminated to a first core dielectric substrate. The metal foil is etched away. Thereafter the graphene layer is etched using oxygen plasma etching to form graphene circuits on the first core dielectric substrate. The first core dielectric substrate having graphene circuits thereon is bonded together with a second core dielectric substrate wherein the graphene circuits are on a side facing the second core dielectric substrate wherein an air gap is left therebetween.

A catheter includes a catheter tube and a Flexible Printed Circuit Board, FPCB, wherein the FPCB covers essentially the catheter circumference for predetermined FPCB transducer segment length, especially at the distal portion, wherein the FPCB in the FPCB transducer segment includes a scaffold structure with a plurality of FPCB free spaces and one FPCB free surface portion creating maximum mechanical stability with the least amount of material and a FPCB scaffold structure which ensures maximum flexibility. The FPCB includes transducer patches which are connected by traces on the straight scaffolds of the scaffold structure. The FPCB free spaces are configured for preventing, circumventing and/or compensating the kinking behavious of the catheter tube.

A wiring body includes: a core insulating base material having a first main surface and a second main surface; a signal line and a first power supply line provided on the first main surface; a second power supply line provided on the second main surface and electrically connected to the first power supply line; a first dielectric layer laminated on the first main surface so as to embed the signal line and the first power supply line; a first ground layer provided on the first dielectric layer; a second dielectric layer laminated on the second main surface so as to embed the second power supply line; and a second ground layer provided on the second dielectric layer and sandwiching at least the signal line together with the first ground layer.

A resin multilayer board includes an insulating substrate including a first main surface and mounting electrodes only on the first main surface. The insulating substrate includes first and second resin layers that are laminated. The Young's modulus of the second resin layers is higher than that of the first resin layers. The first and second resin layers are arranged in a distributed manner along a lamination direction of the first and second resin layers. The insulating substrate includes a first and second portions that are two equally divided portions of the insulating substrate in the lamination direction and are respectively positioned closer to the first main surface and farther from the first main surface, and a volume ratio of the second resin layers in the first portion is higher than a volume ratio of the second resin layers in the second portion.

In a printed circuit board (1) comprising a plurality of insulating layers and conductive layers, and comprising at least one cavity (7) at least one electromagnetic coil (8) is arranged on an outer layer (4) of the printed circuit board (1) and cooperates with a permanent magnet (6) arranged inside the at least one cavity (7).

Provided are circuit board excellent in interlayer adhesion and solder heat resistance, and production method thereof. The circuit board is produced by a method including: preparing a plurality of at least one kind of thermoplastic liquid crystal polymer (TLCP) films, forming a conductor layer on one side or both sides of a film in at least one of the films to obtain a unit circuit board, laminating the films containing the unit circuit board to obtain a stacked material, conducting thermo-compression-bonding of the stacked material under pressurization to a first temperature giving an interlayer adhesion to integrate the stacked material, carrying out structure-controlling thermal treatment by heating the integrated stacked material at a second temperature which is lower than the first temperature and is lower than a melting point of a TLCP having a lowest melting point out of the plurality of TLCP films.