A cross-wiring calibration and positioning method for solder paste printing of a single or multiple pieces of PCB or FPC is provided including: lifting a PCB and FPC to disengage from a lower carrier for suction positioning, recording coordinates by photographing marker points of two points on each single piece of PCB or FPC, comparing the same with absolute coordinates or relative coordinates of marker point coordinates on a solder paste printing steel plate photographed through a solder paste printer, performing compensation calculation and feeding back a signal to an XYθ calibration platform on each profiling sucker, lifting the PCB or the FPC to attach to the solder paste printing steel plate for solder paste printing, lowering the lifted platform, and moving the load to a lower workstation, and then covering the PCB or FPC with an upper steel sheet or an upper carrier.

Extrusion dies and methods of manufacturing extrusions dies, the extrusion die including a first plate and a second plate. The first plate has first upstream and downstream surfaces. A first material of the first plate has a first elastic modulus. The first plate includes pins formed between a plurality of slots. The pins and slots define a discharge face for the extrusion die at the first downstream surface of the first plate. The second plate has second upstream and downstream surfaces. The second plate is joined at the second downstream surface to the first upstream surface of the first plate. A second material of the second plate has a second elastic modulus. The second elastic modulus is greater than the first elastic modulus. A plurality of feed holes extend from the second upstream surface of the second plate through the extrusion die into communication with the slots.

A method to set up the parameters of solder paste screen printer while in a new product introduction (NPI). The method includes establishing a solder-printing database of a predetermined product and a database of different specifications of products, and training a first prediction model by reference to a solder paste screen printer (SPSP) and a solder paste inspection (SPI) based on the solder-printing database. A second prediction model is trained by reference to the SPI based on the database of different products. The method further includes predicting parameters for products with different specifications under multiple sets of printing parameters based on the first and second prediction models. An objective function based on the predicted measurements is established, and a specification of a product and a printing expectation parameters are input to the objective function for outputting many sets of printing-suggestion parameters of the new product.

A printing method for selectively depositing braze powders on a surface comprises extruding a filament from a nozzle moving relative to a surface, where the filament comprises a flowable carrier mixed with a braze powder. As the nozzle moves, the filament is deposited on the surface in a predetermined pattern defined by the motion of the nozzle relative to the surface; thus, the braze powders are deposited at one or more predetermined locations on the surface.

In conventional fluid discharge devices, a discharge head used should be increased in size according to increase in size of a workpiece such as silicon wafer. However, if the discharge head increases in length, a deformation amount of a mask used for discharging the fluid on the workpiece increases, thereby the discharging amount varies. Discharging the fluid in a reciprocating manner is performed using a fluid discharging device including a head unit having a width shorter than a length of the workpiece. A suction port having opening portions each having a slit shape are disposed on the both sides of the discharge nozzle in a vicinity of the discharge nozzle.

The present application provides a method for providing solder paste, for providing solder paste accommodated in a solder paste tub into a solder paste printer, the method comprising: inserting a solder paste nozzle into a housing of the solder paste tub through an opening of the solder paste tub, wherein solder paste is accommodated in the housing of the solder paste tub; bearing the solder paste tub, with the opening facing downward, on a working platform by means of the solder paste nozzle; holding the solder paste tub by mating a holder with an engagement means on an outer wall of the housing of the solder paste tub, the holder being capable of moving up and down with the housing of the solder paste tub; and pressing the housing of the solder paste tub, such that the housing of the solder paste tub moves relative to the solder paste nozzle, at the same time causing the holder to move as the housing of the solder paste tub moves, so as to extrude solder paste accommodated in the housing of the solder paste tub from the solder paste nozzle.

An automatic solder paste feeding system, comprising: a base, a container mounted on the base and configured to contain a solder paste therein, a syringe mounted on the base and configured to inject the solder paste into the container, and a heater mounted on the base and configured to heat the solder paste contained in the container, so that the solder paste is melted into liquid state.

An ejector for jetting a viscous medium onto a substrate is disclosed. The ejector comprises a jetting chamber adapted to accommodate the viscous medium, a nozzle communicatively connected to the chamber, and an impacting device adapted to impact a volume of the viscous medium in the chamber such that viscous medium is jetted through the nozzle towards the substrate. The ejector may further comprise a rotating mechanism adapted to rotate the impacting device around a length axis of the impacting device such that shearing is induced in the viscous medium to be jetted. A corresponding system and method is also disclosed.

A microelectronic device has bump bond structures on input/output (I/O) pads. The bump bond structures include copper-containing pillars, a barrier layer including cobalt and zinc on the copper-containing pillars, and tin-containing solder on the barrier layer. The barrier layer includes 0.1 weight percent to 50 weight percent cobalt and an amount of zinc equivalent to a layer of pure zinc 0.05 microns to 0.5 microns thick. A lead frame has a copper-containing member with a similar barrier layer in an area for a solder joint. Methods of forming the microelectronic device are disclosed.

The present invention relates to a turntable-type probe pin laser bonding apparatus. More particularly, a dual laser optic module of the turntable-type probe pin bonding apparatus of the present invention provides an integrated dual laser optic module that is overlappingly irradiated on a co-focus by improving the conventional first and second laser optic modules that have been completely separated and arranged independently with different focal points. During laser bonding of probe pins, which are getting miniaturized day by day, the power and density of the first and second laser beams overlappingly irradiated from the integrated dual laser optic module can be precisely controlled so that a turntable-type probe pin laser bonding apparatus of the present invention can significantly improve the bonding defect rate, as well as contribute to high integration and high precision of the apparatus.