An electronic device includes: a housing and a printed circuit board (PCB) structure disposed in the housing. The PCB structure includes a circuit board including an opening area formed through a first surface of the circuit board and a second surface of the circuit board opposite the first surface and a conductive pattern formed in a peripheral area around the opening area, a plate disposed on the second surface of the circuit board covering the opening area, an electronic element disposed on the plate and electrically connected with the circuit board, a resin portion disposed between the plate and the circuit board and extending from the conductive pattern, the resin portion including a conductive material, and a solder portion formed between the resin portion and the plate.

An insulated circuit substrate manufacturing method of the present invention includes a metal piece disposing step of disposing the metal piece in a circuit pattern shape on a resin material serving as the insulating resin layer and a bonding step of bonding the insulating resin layer and the metal piece by pressurizing and heating the resin material and the metal piece at least in a laminating direction. In the bonding step, the metal piece and the resin material are pressurized in the laminating direction by a pressurizing jig that includes a cushion material disposed on a side of the metal piece and a guide wall portion disposed at a position facing a peripheral portion of the cushion material, and the peripheral portion of the cushion material is brought into contact with the guide wall portion during pressurization.

The present disclosure illustrates a signal transmission apparatus and a display apparatus using the same. The signal transmission apparatus comprises a first flexible printed circuit board electrically connected to a display module and a system, and comprising a port; and a second flexible printed circuit board electrically connected to the display module, and comprising a port connection member, and the port connection member corresponding to the port. The second flexible printed circuit board is electrically connected to the first flexible printed circuit board through the port connection member and the port, and is further electrically connected to the system. The signal transmission apparatus is used to replace the conventional manner of soldering multiple circuit boards for connection, so as to prevent the variation during the soldering process, and reduce errors of the manufacturing process, and improve yield rate of the display product. Furthermore, compared with the soldering manner, the signal transmission apparatus of the present disclosure improves connection strength between multiple circuit boards.

Embodiments of the present disclosure disclose a flexible printed circuit, a light bar, a backlight module and a liquid crystal display device. The flexible printed circuit includes a substrate and a plurality of groups of LED pads located on the substrate, wherein each group of the LED pads is configured to mount one LED lamp bead, each group of the LED pads includes a first pad, a second pad and a third pad, the firs pad, the second pad and the third pad are arranged sequentially in a first direction, the first pad and the second pad both receive a first voltage signal, the third pad receives a second voltage signal, and the first voltage signal is different from the second voltage signal.

A die bonding method for a micro-LED. The method includes plating tin at a die bonding position of a printed circuit board (PCB) to obtain a tin-plated layer; adding a protective layer and a flux layer on the tin-plated layer in sequence to obtain a pretreated PCB; and transferring a flip-chip micro-LED to the pretreated PCB, reflowing and die bonding to complete die bonding of the micro-LED.

A metal base substrate of the present invention is a metal base substrate including a metal substrate, an insulating layer laminated on one surface of the metal substrate, and a circuit layer laminated on a surface of the insulating layer opposite to the metal substrate side, in which the circuit layer is made of a metal having a semi-softening temperature of 100° C. or higher and 150° C. or lower, the insulating layer contains a resin, and a relationship between a thickness t (μm) of the insulating layer and an elastic modulus E (GPa) of the insulating layer at 100° C. satisfies a following formula (1).

10<t/E  (1)

A light-emitting device includes an insulating base member having thermal conductivity of 10 W/m.Math.K or more; a light-emitting element that has a cathode electrode and an anode electrode and is provided on a front surface side of the base member; a capacitive element that is provided on the base member and supplies an electric current to the light-emitting element; and a reference potential wire that is provided on a rear surface side of the base member and is connected to an external reference potential. The reference potential wire is connected to the capacitive element and is insulated from the cathode electrode and the anode electrode.

A method for manufacturing a semiconductor package structure is provided. The method includes: (a) providing a semiconductor structure including a first device and a second device; (b) irradiating the first device by a first energy-beam with a first irradiation area; and (c) irradiating the first device and the second device by a second energy-beam with a second irradiation area greater than the first irradiation area of the first energy-beam.

The invention relates to a method for soldering an SMD component (1) to a circuit carrier (2) in a positionally stable manner, having the following steps: a) providing a circuit carrier (2) comprising at least one printed circuit board contact surface (2a), which is coated with a soldering paste (3) and which is designed to electrically, thermally and/or mechanically contact the SMD component (1) to be connected, wherein a number of filled vias (6), which cannot be coated with molten solder, pass through the circuit carrier (2) at least in the region of the printed circuit board contact surface (2a), b) applying at least one adhesive point (4a, 4b, 4c, 4d, 4e) onto the circuit carrier (2) such that the adhesive point (4a, 4b, 4c, 4d, 4e) delimits the printed circuit board contact surface (2a) coated with soldering paste (3) on at least one side of an edge point (R.sub.a, R.sub.b) paired with the soldering paste (3), c) placing an SMD component (1), which comprises at least one component contact surface (1a), on the printed circuit board contact surface (2a) coated with soldering paste (3) such that the at least one component contact surface (1a) electrically, thermally and/or mechanically contacts the printed circuit board contact surface (2a) via the soldering paste (3) lying therebetween, said placement being carried out and the position of said at least one adhesive point (4a, 4b, 4c, 4d, 4e) being selected in step b) such that the SMD component (1) rests on the soldering paste (3) without contacting the at least one adhesive point (4a, 4b, 4c, 4d, 4e), d) waiting for a specifiable duration t until a curing process of the at least one adhesive point (4a, 4b, 4c, 4d, 4e) is complete, and e) heating, melting and subsequently cooling the soldering paste (3) in order to produce an electric, thermal and/or a mechanical connection between the at least one component contact surface (1a) of the SMD component (1) and the at least one printed circuit board contact surface (2a) of the circuit carrier (2), wherein a barrier (5) is formed using the at least one adhesiv

There is provided a manufacturing method for an insulating resin circuit substrate, which is a manufacturing method for an insulating resin circuit substrate which includes an insulating resin layer composed of a polyimide resin and a circuit layer consisting of metal pieces disposed in a circuit pattern shape on one surface of the insulating resin layer. The manufacturing method includes a temporary fixing step of pressurizing the metal pieces toward the resin sheet material while heating the metal pieces to temporarily fix the metal pieces and a joining step of disposing a cushion material on a side of the metal pieces which are temporarily fixed and pressurizing the metal pieces and the resin sheet material in a laminating direction, while heating the metal pieces and the resin sheet material, to join the resin sheet material and the metal pieces.