The present invention includes: an ultrasonic horn (14) to which two ultrasonic vibrations can be input to excite a capillary (15) mounted to a front end with different frequencies in a Y-direction and an X-direction; and a control unit (50) which adjusts the respective magnitude of the two ultrasonic vibrations. The Y-direction is a direction in which the ultrasonic horn (14) extends. The control unit (50) adjusts the respective magnitude of the two ultrasonic vibrations to adjust a ratio (ΔY/ΔX) of amplitude of the capillary (15) in the Y-direction and the X-direction. Thus, degradation in the quality of the joining between wires and leads is suppressed.

The invention relates to an ultrasonic metal welding device and a method for welding electrical conductors using a compression chamber that is adjustable at least in height and that is delimited on opposite sides by a section of a sonotrode as a first delimiting surface and by at least one section of a counter electrode (156) as a second delimiting surface, wherein for welding, the counter electrode and the sonotrode are displaced relative to one another. The counter electrode used is one that comprises sections (152, 154) of geometrically different working surfaces or is composed of at least two sections that are displaceable relative to one another.

An ultrasonic horn is provided with: a vibration generating unit configured to generate longitudinal vibration having a frequency in the ultrasonic band on the basis of a signal having a frequency in the ultrasonic band input from an oscillator; a vibration amplifying unit configured to amplify the vibration generating unit while transmitting the longitudinal vibration from the vibration generating unit; and a longitudinal-torsional vibration conversion slit unit having slits formed in a groove-like shape on the surfaces of the vibration amplifying unit and configured to convert the longitudinal vibration into torsional vibration. The vibration amplifying unit has a polygonal shape in a plane view, and has a plurality of surfaces provided with slits along with a surface not provided with slits.

A guide wire with improved joining strength is provided. The guide wire includes a first wire and a second wire are solid-phase-joined to each other, the first wire and the second wire are made of a Ni—Ti-based alloy. When a section of a crystal grain size is 1 μm in a number-based particle size distribution of crystal grains of a metallographic structure of a joint surface between the first wire and the second wire, the frequency of the crystal grains having a mode particle size is 25% or more and the frequency of the crystal grains having a crystal grain size with a representative diameter of (mode particle size (μm)−1 μm) or more and (mode particle size (μm)+1 μm) or less is 60% or more.

A method of forming a wire loop in connection with a semiconductor package is provided. The method includes the steps of: (1) providing package data related to the semiconductor package to a wire bonding machine; (2) providing at least one looping control value related to a desired wire loop to the wire bonding machine, the at least one looping control value including at least a loop height value related to the desired wire loop; (3) deriving looping parameters, using an algorithm, for forming the desired wire loop; (4) forming a first wire loop on the wire bonding machine using the looping parameters derived in step (3); (5) measuring actual looping control values of the first wire loop formed in step (4) corresponding to the at least one looping control value; and (6) comparing the actual looping control values measured in step (5) to the at least one looping control value provided in step (2).

According to a first aspect of the present invention, there is provided a bond apparatus for bonding a wire to a bonding surface, comprising: a bond head body movably retained by a mounting portion; a first actuator; and a second actuator, wherein the bond head body has a tool portion configured to receive a bonding tool for receiving and bonding the wire and an actuator portion coupled with the first actuator and the second actuator, the first actuator and the second actuator being operative to act on the actuator portion for moving the bond head body with respect to the mounting portion to move the bonding tool with respect to the bonding surface.

An ultrasonic tool including a first end face and a second end face opposite the first end face. A tool lateral surface connects the first and second end face. The ultrasonic tool is elongate in a longitudinal direction of the tool, wherein at least the first end face is designed as a connection contact surface that is arranged for pressing the ultrasonic tool against a connection component, wherein the ultrasonic tool has an end region having the connection contact surface, which end region extends from the connection contact surface in the longitudinal direction of the tool over 15 mm, but at most one third of a length of the ultrasonic tool, toward the opposite end face, and wherein a pocket-shaped and/or blind-hole-like recess having a recess lateral surface and having a recess floor facing the connection contact surface is formed at the tool lateral surface in the end region.

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 method for bonding large modules with the following steps, a large module is fed to a bonder from behind in a loading plane by means of a feeder unit. The large module is passed from the feeder unit to a first transverse conveyor unit, and is brought by the same to a first buffer position provided in the bonder, wherein the first buffer position is provided in a loading plane of the bonder. The large module is brought from the first buffer position into a first receiving position in the loading plane via the first transverse conveyor unit and is passed there to a vertical conveyor unit.

In a described example, an electrical apparatus includes a substrate having a first surface and lead pads on the first surface of the substrate for surface mounting components. A ribbon wire bond is provided having open ends and a central portion between the open ends, the open ends of the ribbon wire bond connected to the lead pads. An electrical component is bonded to the central portion of the ribbon wire bond. The central portion of the ribbon wire bond and the electrical component are spaced from the first surface of the substrate.