The invention provides a printed circuit board (10) including a first electrically conductive track (210), wherein the printed circuit board (10) comprises a set (15) of two printed circuit board areas (100) both comprising a part of the first electrically conductive track (210), wherein printed circuit board (10) further comprises a perforation line (300) between the two printed circuit board areas (100) for customizing the printed circuit board (10) into two physically separated printed circuit board area comprising parts (1100), wherein the perforation line (300) is configured as a non-straight line, wherein the perforation line (300) comprises relative to one of the printed circuit board areas (100), and in a plane of the printed circuit board (10), a first projecting part (311) and a first recessed part (312), wherein the first recessed part (312) is recessed relative to the first projecting part (311), wherein the first electrically conductive track (210) is intercepted by the perforation line (300) at the first recessed part (312).

An apparatus for manufacturing a display device includes a plurality of working tables, a plurality of arm modules, and a rotator. The plurality of working tables are spaced apart from each other in a first direction and are configured to support a target board. The plurality of arm modules are arranged in the first direction and spaced apart from the plurality of working tables in a second direction intersecting the first direction. The rotator is connected to the plurality of arm modules and configured to rotate about a rotation axis extending in the first direction.

A method of manufacturing a curved electronic device (100) and resulting product. A patterned layer of non-conductive support material (12m) is printed onto a thermoplastic substrate (11) to form a support pattern. An electrical circuit (13,14) is applied onto the support pattern (12), wherein the electrical circuit (13,14) comprises circuit lines (13) comprising a conductive material (13m) applied onto support lines (12b) of the pattern and electrical components (14) applied onto support islands (12a) of the pattern. A thermoforming process (P) is used for deforming (S) the substrate (11) while a relatively high resistance of the support material (12m) to the deforming maintains a structural integrity of the electrical circuit (13,14).

A technique that improves productivity of a functional module on which a component is implemented near an edge. A multi-pattern substrate includes wiring substrate parts, and waste substrate parts provided around the wiring substrate parts integrally. And openings are provided in the waste substrate parts in areas that face components implemented near outer circumferences of the wiring substrate parts.

A method of manufacturing a curved electronic device (100) and resulting product. A patterned layer of non-conductive support material (12m) is printed onto a thermoplastic substrate (11) to form a support pattern. An electrical circuit (13,14) is applied onto the support pattern (12), wherein the electrical circuit (13,14) comprises circuit lines (13) comprising a conductive material (13m) applied onto support lines (12b) of the pattern and electrical components (14) applied onto support islands (12a) of the pattern. A thermoforming process (P) is used for deforming (S) the substrate (11) while a relatively high resistance of the support material (12m) to the deforming maintains a structural integrity of the electrical circuit (13,14).

A main board for a computer device can include main board components arranged on a first surface of the main board and Trusted Platform Module (TPM) components arranged on the first surface of the main board. The TPM components can be located in a predetermined area of the main board that is detachable from the main board (e.g. by means of a predetermined break line). A method for producing an embodiment of the main board with an integrated TPM can include producing a Printed Circuit Board (PCB); arranging a plurality of main board components in a first area of the PCB; and arranging TPM components in a second area of the PCB that is a detachable predetermined area of the main board. A predetermined breakline which at least partly surrounds the predetermined area can be formed by drilling holes to form a perforated line.

An electrical interconnection system for electrical components of a module includes a hub printed circuit board (PCB) having a first electrically conductive track and a second electrically conductive track. Each of the first and second electrically conductive tracks is configured to electrically connect at least two of the electrical components of the module, wherein the at least two of the electrical components of the module are external to the hub PCB. The system also includes multiple electrical terminals, wherein each of the electrical terminals is configured to electrically connect one of the first and second electrically conductive tracks of the hub PCB to one of the at least two electrical components of the module.

The invention relates to the field of techniques for manufacturing electronic devices having surface-mounted components, and can be used in avionics, telecommunication, lighting technology, and other fields, and can be configured as a power source, a converter, sensors, etc. The technical result consists in improved weight and dimension characteristics, improved heat dispersion, and increased electromagnetic screening. The present electronic module comprises a printed circuit board in the form of a three-dimensional structure, faces of which are formed by flat sections of the printed circuit board, and edges of which are formed by fold lines between the sections of the printed circuit board, wherein the mounting surface of the printed circuit board faces the inside of the three-dimensional structure, and electronic components and assemblies are grouped on the mounting surface of at least two sections of the printed circuit board such that the electronic components and assemblies of one section are disposed in the empty space between the components and assemblies of another section of the printed circuit board.

A resin multilayer substrate includes a stacked body including a first main surface, a cavity provided in the first main surface, and conductor patterns provided in the stacked body. The stacked body includes insulating substrate layers including resin as a main material that are stacked. The cavity includes a side surface and a bottom surface. At least a portion of a boundary between the side surface and the bottom surface includes conductor patterns continuous with the side surface and the bottom surface.

The invention provides a printed circuit board (10) including a first electrically conductive track (210), wherein the printed circuit board (10) comprises a set (15) of two printed circuit board areas (100) both comprising a part of the first electrically conductive track (210), wherein printed circuit board (10) further comprises a perforation line (300) between the two printed circuit board areas (100) for customizing the printed circuit board (10) into two physically separated printed circuit board area comprising parts (1100), wherein the perforation line (300) is configured as a non-straight line, wherein the perforation line (300) comprises relative to one of the printed circuit board areas (100), and in a plane of the printed circuit board (10), a first projecting part (311) and a first recessed part (312), wherein the first recessed part (312) is recessed relative to the first projecting part (311), wherein the first electrically conductive track (210) is intercepted by the perforation line (300) at the first recessed part (312).