An electronic system for identifying an article can include a printed memory having a plurality of contact pads electrically coupled to a plurality of landing pads positioned on a first side of a printed circuit board (PCB) substrate. The plurality of landing pads can be electrically coupled to a plurality of endless, concentric contact lines positioned on a second side of the PCB substrate through a plurality of vias that extend through a thickness of the PCB substrate and a plurality of traces that electrically couple the plurality of vias with the plurality of landing pads. To perform a memory operation on the printed memory, contact probes of a reader are physically and electrically contacted with the plurality of concentric contact lines. In some implementations, the memory operation can be performed on the printed memory irrespective of a rotational orientation of the printed memory relative to the reader.

The present invention provides a method for manufacturing a backlight source. The method for manufacturing a backlight source according to the present invention forms a plurality of tin soldering pattern groups on a substrate. Each tin soldering pattern group includes tin soldering patterns spaced from one another, and the tin soldering patterns are in a closed ring shape. The Mini-LEDs are disposed on the tin soldering pattern groups respectively. The substrate is placed in the space having a varying magnetic field. The circuit of the tin soldering patterns in the tin soldering pattern groups generates the induced current for rapid heating and melting, to solder the Mini-LEDs on the substrate. The soldering speed is improved, the process efficiency is high, the process cost is low, and the light effect of the backlight source is effectively ensured.

A manufacturing method of the light-emitting diode package structure is provided. A carrier is formed. The carrier comprises a first build-up circuit. At least one self-assembled material layer is formed on the first build-up circuit. A first solder mask layer is formed on the first build-up circuit. The first solder mask layer has at least one opening to expose a portion of the at least one self-assembled material layer. At least one light-emitting diode is disposed on the first build-up circuit. The at least one light-emitting diode has a self-assembled pattern, and the at least one light-emitting diode is self-assembled into the at least one opening of the first solder mask layer through a force between the self-assembled pattern and the at least one self-assembled material layer.

A conveyor system for a stencil printer includes a pair of rail members extending through a frame and configured to transport the substrate through the stencil printer. A lift tool assembly is configured to support the substrate at a transport height and a print height. The lift tool assembly includes a lifter portion configured to be engaged by a support of the lift table assembly. A foot of the lifter portion has at least two permanent magnets configured to secure the foot of the lifter portion to the support when engaging the support to the lifter portion, and at least one vacuum pocket formed in a bottom surface of the foot of the lifter portion. The vacuum pocket is configured to selectively secure the lifter portion in place on the support.

A conveyor system for a stencil printer includes a pair of rail members, with the pair of rail members extending through a frame and configured to transport the substrate through the stencil printer. The conveyor system further includes, for each rail member, a lift tool assembly coupled to the rail member. The lift tool assembly includes a lifter portion, a main plate secured to the lifter portion, and a clamping member coupled to the main plate. The clamping member is configured to move horizontally between a substrate engaged position and a substrate disengaged position. The lift tool assembly further includes a thin foil coupled to the main plate. The thin foil is configured to move vertically and horizontally, independent from the clamping member.

A light-emitting diode package structure includes a carrier, at least one self-assembled material layer, a first solder mask layer, and at least one light-emitting diode. The carrier includes a first build-up circuit. The self-assembled material layer is disposed on the first build-up circuit. The first solder mask layer is disposed on the first build-up circuit. The first solder mask layer has at least one opening to expose a portion of the self-assembled material layer. The light-emitting diode is disposed on the first build-up circuit. The light-emitting diode has a self-assembled pattern. The light-emitting diode is self-assembled into the opening of the first solder mask layer through a force between the self-assembled pattern and the self-assembled material layer. A manufacturing method of the light-emitting diode package structure is also provided.

Systems and methods for improved interconnections for electronic components using ACAs are provided. The methods involve using magnets specific for each component to be connected and optimized in terms of size and strength and position relative to the substrate and component. Also provided are ovens adapted for use with the methods and systems and kits providing the parts of the system for use with existing ovens.

Disclosed is a battery pack, which includes a plurality of stacked cells; a board assembly including interconnect circuit boards (ICBs) arranged corresponding to cell leads; an ICB cover detachably coupled to the board assembly; and a magnet installed at the ICB cover and coupled to the ICB by a magnetic force thereof with the cell lead being interposed therebetween, wherein the lead is closely fixed to the ICB by means of the magnetic force acting between the ICB and the magnet.

An electric device which includes a first component carrier structure with a first magnet structure and a first connection structure, and a second component carrier structure with a second magnet structure and a second connection structure. The first magnet structure and the second magnet structure are configured such that upon attaching the first component carrier structure and the second component carrier structure to one another the first connection structure is connected to the second connection structure, holding the first component carrier structure and the second component carrier structure together by an attracting magnetic force between the first magnet structure and the second magnet structure.

A self-heating solder flux material includes a solder flux material and a multi-compartment microcapsule. The solder flux material includes a solvent carrier, and the multi-compartment microcapsule includes a first compartment, a second compartment, and an isolating structure. The first compartment contains a first reactant, and the second compartment contains a second reactant. The isolating structure separates the first compartment from the second compartment. The isolating structure is adapted to rupture in response to a stimulus.