A display device and a manufacturing method thereof are provided. The display device includes a display panel and a flexible circuit board electrically connected with the display panel. The flexible circuit board includes a first circuit board, a second circuit board and a conductive portion; the first circuit board includes a first substrate, and a main contact pad, a first wire and a second wire provided on the first substrate; the second circuit board includes a second substrate, a relay contact pad and a third wire provided on the second substrate; and the conductive portion is configured for electrically connecting the main contact pad and the relay contact pad.

A display device and a manufacturing method thereof are provided. The display device includes a display panel and a flexible circuit board electrically connected with the display panel. The flexible circuit board includes a first circuit board, a second circuit board and a conductive portion; the first circuit board includes a first substrate, and a main contact pad, a first wire and a second wire provided on the first substrate; the second circuit board includes a second substrate, a relay contact pad and a third wire provided on the second substrate; and the conductive portion is configured for electrically connecting the main contact pad and the relay contact pad.

A display device and a manufacturing method thereof are provided. The display device includes a display panel (20) and a flexible circuit board electrically connected with the display panel (20). The flexible circuit board includes a first circuit board (11), a second circuit board (22) and a conductive portion; the first circuit board (11) includes a first substrate (100), and a main contact pad, a first wire (501) and a second wire (502) provided on the first substrate (100); the second circuit board (22) includes a second substrate (200), a relay contact pad and a third wire (210) provided on the second substrate (200); and the conductive portion is configured for electrically connecting the main contact pad and the relay contact pad.

In a printed circuit board (1), thermal vias (19) are formed between the lower surface (A) and an upper surface (B) of the substrate plate (10) of the printed circuit board through the steps of: applying a respective solder resist mask (21, 31) to the lower surface (A) and the upper surface (B); applying solder to the lower surface (A) and reflow soldering the solder, wherein the solder penetrates into the boreholes (20) and forms convex menisci (26) protruding beyond the edge (22) of the respective boreholes on the lower surface (A); and creating regions (35) on the upper surface (B), which are freed from solder resist material, and which are intended for contacting at least one electronic component (17) on the upper surface and each of which comprise at least one of the thermal vias. Subsequently, the upper surface (B) can be provided with electrical components (17) on these regions (35). The first solder resist mask (21) has a respective region (23) that is free of solder resist on the lower surface around the edge of every borehole (20).

Disclosed are a printed circuit board manufactured by filling a via hole formed in a flexible board and a via hole formed in a cured base substrate and then laminating the flexible board and the cured base substrate and a method of manufacturing same. The method includes preparing a flexible board including a flexible region and a rigid region, preparing a cured base substrate, and laminating the cured base substrate on the rigid region of the flexible board, in which during the laminating, via holes respectively formed in the flexible board and the cured base substrate are first filled with a conductive material and then the flexible board and the cured base substrate are laminated.

Filing a plated through-hole of a circuit board with solder is facilitated by an apparatus which includes a wire solder assembly and a controller. The wire solder assembly includes a wire probe sized to extend into the plated through-hole from one side of the circuit board, and a solder block associated with the wire probe so that the probe passes through the solder block. The controller controls heating of the wire probe, when the wire probe is operatively inserted into the plated through-hole, by passing a current through the wire probe. The heating of the wire probe heats a conductive plating of the plated through-hole and melts the solder block. The heating of the conductive plating and the melting of the solder block causes the solder to migrate into the plated through-hole by capillary action to fill the plated through-hole with the solder.

A method for repairing a through-hole includes inserting a repair coil, comprising a tightly-wound repair strip, into a through-hole and inserting a heating element into the repair coil. Passing an electrical current through the heating element liquefies a bonding material disposed on the repair coil and the repair coil expands within the through-hole. Subsequently solidifying the bonding material bonds the repair coil to the through-hole. A repair assembly comprises a repair coil inserted into a through-hole and a heating element inserted into the repair coil. The repair coil comprises a tightly-wound repair strip. The heating element comprises a segment of a heating wire enclosed within an insulating material. Passing an electric current through the segment of the heating wire liquefies bonding material disposed on the repair coil and the repair coil expands within the through-hole. The liquified bonding material solidifies to bond the repair coil to the through-hole.

Fabrication of a reliable circuit board assembly with soldered, plated through-hole structures is facilitated by characterizing plating of a plated through-hole of the circuit board using time-domain reflectance to obtain a base reflectance measurement, and applying solder to the plated through-hole. Based on applying the solder, the plating of the plated through-hole of the circuit board is re-characterized using time-domain reflectance to obtain a new reflectance value. Based on a deviation between the new reflectance measurement and the base reflectance measurement exceeding a threshold, dissolution, at least in part, of the plating of the plated through-hole due to applying the solder is identified.

A method for repairing a through-hole includes inserting a repair coil, comprising a tightly-wound repair strip, into a through-hole and inserting a heating element into the repair coil. Passing an electrical current through the heating element liquefies a bonding material disposed on the repair coil and the repair coil expands within the through-hole. Subsequently solidifying the bonding material bonds the repair coil to the through-hole. A repair assembly comprises a repair coil inserted into a through-hole and a heating element inserted into the repair coil. The repair coil comprises a tightly-wound repair strip. The heating element comprises a segment of a heating wire enclosed within an insulating material. Passing an electric current through the segment of the heating wire liquefies bonding material disposed on the repair coil and the repair coil expands within the through-hole. The liquified bonding material solidifies to bond the repair coil to the through-hole.

In a printed circuit board (1), thermal vias (19) are formed between the lower surface (A) and an upper surface (B) of the substrate plate (10) of the printed circuit board through the steps of: applying a respective solder resist mask (21, 31) to the lower surface (A) and the upper surface (B); applying solder to the lower surface (A) and reflow soldering the solder, wherein the solder penetrates into the boreholes (20) and forms convex menisci (26) protruding beyond the edge (22) of the respective boreholes on the lower surface (A); and creating regions (35) on the upper surface (B), which are freed from solder resist material, and which are intended for contacting at least one electronic component (17) on the upper surface and each of which comprise at least one of the thermal vias. Subsequently, the upper surface (B) can be provided with electrical components (17) on these regions (35). The first solder resist mask (21) has a respective region (23) that is free of solder resist on the lower surface around the edge of every borehole (20).