A FPC flattening jig and a FPC flattening method. The FPC flattening jig includes a pressurization mechanism and a heating mechanism; a bottom of the pressurization mechanism has a planar base surface which is used to contact a warped FPC to exert pressure thereon; the heating mechanism is used to heat the pressurization mechanism, such that the planar base surface of the pressurization mechanism has a predefined temperature when exerting pressure on the FPC. The FPC flattening jig heats the pressurization mechanism by a heating mechanism, and then the heated planar base surface of the pressurization mechanism contacts the warped FPC and exerts pressure thereon. Therefore, the FPC can be flattened. As such, the FPC can be reused, facilitating the improvement on the recycling rate of FPC.

An ultrasonic bonding head includes a vibrator unit, a holder, and a pressurizing shaft. The vibrator unit includes a press part formed at a tip of the vibrator unit in a longitudinal axis thereof and configured to press a bonding scheduled part to be bonded. The holder holds a base of the vibrator unit in a cantilever manner so that the tip is a free end. The pressurizing shaft is connected with the holder and transmits a force of pressing the press part against the bonding scheduled part so that the vibrator unit moves substantially perpendicularly to the longitudinal axis. The holder is provided with a restraint portion. The restraint portion contacts with the vibrator unit at a counterforce dispersion position located between a main hold position for holding the vibrator unit by the holder and the free end.

A shield enclosure includes a housing with a peripheral wall that defines a cavity, and a cover removably coupleable to the housing to at least partially seal the cavity. The cavity is sized to receive a printed circuit board therein. The housing shields the printed circuit board from electromagnetic interference and noise during noise figure testing of a radiofrequency component on the printed circuit board.

A vertical circuit board printer includes a multi-layer conveyor, a printer assembly, and a control system. The multi-layer conveyor includes a number of front conveyors and one rear conveyor. Each upper front conveyor is coupled to a lower front conveyor by a circuit board-lowering mechanism to transport a number of circuit boards in sequence from the number of front conveyors to the rear conveyor. The printer assembly includes a number of printers arranged in sequence above the number of front conveyors. The control system controls operation of the multi-layer conveyor and controls operation of the printing assembly through a software system.

A method of manufacturing printed circuit boards includes some or all of: chemically or electrically applying metallic layers to a substrate; incorporating bores into the substrate; through-contacting the bores incorporated into the substrate; applying a layer from a photoresist to an electrically conducting layer in a masking step; exposing the photoresist while using an exposure mask in an exposing step; removing exposed or unexposed regions of the layer from the photoresist while in regions laying bare the electrically conducting layer in a developing step; removing the laid-bare regions of the electrically conducting layer in an etching step; cleaning the substrate in a rinsing step; and drying the substrate, wherein the substrate for carrying out the developing step and/or the etching step is set in rotation and a developer solution and/or an etching liquid is applied to the rotating substrate by at least one nozzle.

A method of manufacturing printed circuit boards includes some or all of: chemically or electrically applying metallic layers to a substrate; incorporating bores into the substrate; through-contacting the bores incorporated into the substrate; applying a layer from a photoresist to an electrically conducting layer in a masking step; exposing the photoresist while using an exposure mask in an exposing step; removing exposed or unexposed regions of the layer from the photoresist while in regions laying bare the electrically conducting layer in a developing step; removing the laid-bare regions of the electrically conducting layer in an etching step; cleaning the substrate in a rinsing step; and drying the substrate, wherein the substrate for carrying out the developing step and/or the etching step is set in rotation and a developer solution and/or an etching liquid is applied to the rotating substrate by at least one nozzle.

A system for controlled motion of circuit components to create reconfigurable circuits comprising: a support; a substrate operatively associated with the support; actuators operatively associated with the support configured to physically move circuit components and to move the circuit components into physical and electrical contact with the substrate; the substrate comprising at least one conductive segment arranged to electrically connect circuit components when electrical contacts of circuit components are placed in contact with at least one conductive segment; and control circuitry configured to control the first and second actuators to thereby position the circuit components relative to the substrate; whereby circuit function is determined by the selection of circuit components and the location and orientation of circuit components relative to the substrate and conductive segments to create a reconfigurable circuit.

A clamping device which uses its own weight to apply pressure during a soldering operation to a solderable part or component for attachment to a circuit board is provided. The clamping device includes a base plate and at least one press block which is configured to be arranged on the base plate and is free to move up or down by gravity relative to the base plate. When the gravitational orientation of the clamping device is correct, the press block moves down relative to the base plate and so presses on the solderable part during soldering.

A carrier monitoring system and a method thereof are disclosed. The carrier monitoring system includes carriers for carrying and positioning at least one circuit board, and a reflow oven including a conveyor, a processing module and a database. When one of the carriers is placed on the conveyor, some sensing units are pressed by a plurality of bumps disposed on a bottom of the carrier, and each of the pressed sensing units transmits a sensing signal to the processing module. According to the sensing signals, the processing module obtains a carrier code; and, according to a plurality of identification codes stored in the database and the carrier code, the processing module can determine which carrier is placed on the conveyor. As a result, the technical effect of monitoring the carrier entering the reflow oven can be achieved.

A system for controlled motion of circuit components to create reconfigurable circuits comprising: a support; a substrate operatively associated with the support; actuators operatively associated with the support configured to physically move circuit components and to move the circuit components into physical and electrical contact with the substrate; the substrate comprising at least one conductive segment arranged to electrically connect circuit components when electrical contacts of circuit components are placed in contact with at least one conductive segment; and control circuitry configured to control the first and second actuators to thereby position the circuit components relative to the substrate; whereby circuit function is determined by the selection of circuit components and the location and orientation of circuit components relative to the substrate and conductive segments to create a reconfigurable circuit.