A bonding apparatus can include a console which controls bonding of at least one wire, a first bonding unit disposed on the console to bond a first wire to a first substrate, a second bonding unit disposed on the first bonding unit to bond a second wire to a second substrate different from the first substrate, and a vibration damping unit connected to the second bonding unit preventing vibrations generated in the second bonding unit from transmitting to the first bonding unit.

Various embodiments of the present technology may comprise a method and apparatus for improved bonding and may operate in conjunction with a main platform configured to support a substrate. Movable members may allow the substrate to be positioned on the main platform when rotated to a first position and apply a force to a predetermined area on an upward facing surface of the substrate when rotated to the second position.

A wire splicing method including: disposing an end portion of a tape-like first wire and an end portion of a tape-like second wire in a holding base in an overlapping manner with solder interposed therebetween, pressing a heating body to the first wire and the second wire via a pressing plate, and pressing together and heating the first wire and the second wire so as to melt the solder; keeping the first wire and the second wire pressed together by the pressing plate; separating the heating body from the pressing plate; and cooling the pressing plate to solidify the solder, and thereby connecting the first wire and the second wire together.

Method for producing wire bond connections between an electronic component or a module and a substrate with energy input into a bonding wire by an ultrasonic transducer, wherein during the energy input for forming a first wire bond connection, at least one bonding parameter characterizing the instantaneous state of the bonding wire is measured in dependence on time, the curve shape of the time dependence is differentiated by means of predetermined comparative criteria or curves into three curve sections and hereby the temporal course of the method into three phases, to be specific, a cleaning, a fusion and a tempering phase, and the energy fed into the ultrasonic transducer and/or the bonding force exerted on the bonding wire and/or the duration of the energy input into at least one partial section of at least the cleaning and the fusion phase, in particular each of the cleaning, fusion and tempering phases is/are controlled independent of the measurement result in quasi real time during the formation of the first wire bond connection or during the subsequent formation of a second wire bond connection of the same type in dependence on the curve shape in the associated curve section in a phase-specific manner.

A wire fusing apparatus including a first body having a first surface, a second body having a second surface, and a heating unit is provided. The second body is pivoted to the first body to rotate relatively to the first body enabling the first and second bodies to be in an expanded or a closed state. When the first and second bodies are in the closed state, the first and second surfaces define a closed containing groove for containing two independent wires butt jointed with each other. The first surface, the second surface and the containing groove each has a heat-conducting region, and the heat-conducting regions contact each other when the first and second bodies are in the closed state. The heating unit disposed on the first or second body contacts one of the heat-conducting regions for heat-fusing a butt-jointing point of the wires to form a fused wire.

A metal wiring bonding structure 100 comprises contacts 753 of connection FPC 75 and heater lands 46 of a sheet heater 30 to be bonded by a solder bonding member 766. A connection FPC 75 includes contact opposed lands 754 formed of metal and disposed at positions respectively opposed to the plurality of contacts 753 on a surface of a support layer 751 opposite from a surface on which metal wires 750 are provided. In addition to base surfaces 461 opposed to the contacts 753, the heater lands 46 respectively include extended surfaces 462 opposed to imaginary extended portions 753b imaginarily extended ahead from the contacts 753. A solder bonding member 756 covers surfaces of the contact opposed lands 754, a distal end surface of the connection FPC 75, and the extended surfaces 462 of the heater lands 46, and is filled in a bonding space C.

A wedge bonding tool including a body portion including a tip portion is provided. The tip portion includes a working surface configured to contact a wire material during formation of a wedge bond. A plurality of notches are defined by one or more surfaces of the body portion.

A wire splicing method including: disposing a tape-like first wire and a tape-like second wire in a holding base so that an end portion of the first wire and an end portion of the second wire face each other; disposing solder to straddle the first wire and the second wire; disposing a connection wire on the solder; pressing a heating body to the first wire, the second wire, and the connection wire via a pressing plate, and pressing together and heating the first wire, the second wire, and the connection wire so as to melt the solder; keeping the first wire, the second wire, and the connection wire pressed together by the pressing plate; separating the heating body from the pressing plate; and cooling the pressing plate to solidify the solder, and thereby connecting the first wire and the second wire together.

A ribbon bonding tool is provided. The ribbon bonding tool includes a body portion including a tip portion, the tip portion defining a working surface. The ribbon bonding tool includes a group of four protrusions extending from the working surface, wherein the working surface defines four quadrants in a horizontal plane by extending an imaginary line at a midpoint along each of a length and a width of the working surface. Each of the four protrusions is arranged in one of four quadrants.

A method of manufacturing a semiconductor device includes: a wire tail forming step of forming a wire loop 130 between a first bonding point and a second bonding point with a bonding tool 40, and then cutting a portion of a wire 42 extending from a tip of the bonding tool 40 to thereby form a wire tail 43 at the tip of the bonding tool 40; and a wire tail bending step of bending the wire tail 43 so as to direct a tip 43a of the wire tail 43 upward by descending the bonding tool 40 toward the second bonding point with the wire loop 130 formed thereat and pressing the wire tail 43 against a portion of the wire loop 130 located above the second bonding point. Thus, the wire tail can be bent easily and efficiently.