Abstract: When a semiconductor chip is mounted using ultrasonic vibration, a method of mounting makes it possible to bond the semiconductor chip and bonding patterns with sufficient bonding strength without making the construction of a circuit board complex. The method of mounting a semiconductor chip causes ultrasonic vibration to act on the semiconductor chip to mount the semiconductor chip on a circuit board by flip-chip bonding. As the circuit board, a circuit board is used where protrusion patterns are provided at positions on bonding patterns to which the semiconductor chip is bonded corresponding to antinodes of vibration for a case where the bonding patterns resonate due to ultrasonic vibration applied by the semiconductor chip.

Abstract: A method of assembling a carriage assembly that is operable, during a crimping step that passes a ball, which has a diameter that is equal to or larger than an inner diameter of spacer holes of suspensions, successively through the spacer holes using a bar-shaped pressing member that is subjected to ultrasonic vibration to thereby crimp spacer hole inner circumferential portions of the spacer portions and attach the suspensions to the front end portions of the carriage arms, to prevent the pressing member that presses the ball from colliding with an inner circumferential surface and the like of the spacer holes of the spacer portions and is therefore able to substantially eliminate tilting from the standard angle of the suspensions due to deformation of the spacer portions, and an assembling apparatus that uses such method are provided.

Abstract: There are provided a method of assembling a carriage assembly that can uniformly crimp edge portions of spacer holes of spacer portions and keep the spacer portions flat, thereby maintaining the angles of suspensions with high accuracy, and an assembling apparatus that uses such method.

Abstract: According to an aspect of the invention, an electronic part includes a substrate having a first planar surface, a first bump affixed to the first planar surface of the substrate, a second bump affixed to the first planar surface of the substrate a predetermined distance from the first bump, a MEMS chip including a element, the MEMS chip coupled to the first bump and the second bump, the MEMS chip distanced from the first planar surface, an adhesive region bonding with the first bump, the substrate and the MEMS chip.

Abstract: A method of assembling a carriage assembly is capable of suppressing deformation of spacer portions when suspensions are attached to carriage arms. The method of assembling a carriage assembly aligns fitting holes provided in front end portions of carriage arms and spacer holes provided in spacer portions of suspensions and places the suspensions onto the carriage arms, and then presses a ball with a diameter equal to or greater than an inner diameter of the spacer holes with a pressure-applying member to pass the ball through the spacer holes, thereby crimping spacer hole edge portions of the spacer portions and attaching the suspensions to the front end portions of the carriage arms. By applying ultrasonic vibration from two axial directions to the pressure-applying member, the pressure-applying member is caused to vibrate on a two-dimensional movement path on a predetermined plane and passes the ball through the spacer holes while causing the ball to rotate.

Abstract: When crimping suspensions to carriage arms using a metal ball by applying ultrasonic vibration to a crimping tool, the suspensions can be crimped to the carriage arms without causing deformation to the suspensions and the like. A method of assembling a carriage assembly aligns attachment holes provided in front ends of carriage arms and crimping portions provided on suspensions to set the suspensions on the carriage arms and then presses a ball through crimping holes provided in the crimping portions while applying ultrasonic vibration to the crimping tool to crimp the suspensions to the carriage arms. When doing so, a ball, such as a ball whose surface has been subjected to a dimpling process, for which a load that acts on the ball when the ball passes through the crimping holes is low compared to a spherical ball is used to crimp the suspensions to the carriage arms.

Abstract: According to an aspect of an embodiment, a wire bonding method includes vibrating a capillary of a bonding head, the capillary having a heater attached thereto at a position corresponding to a node of vibration of the capillary generated by the vibration heating the capillary with the heater and performing a wire bonding operation while heating the capillary with the heater.

Abstract: A slider tester includes a driving unit that rotates a test medium, a set plate that detachably supports a slider as a single body, and an investigating apparatus that is electrically connected to the slider supported by the set plate and investigates the characteristics of the slider. A movable support part 30 that tiltably supports the slider is provided on the set plate. There is also provided a pressing mechanism that elastically presses the slider via the movable support part toward a surface of the medium to dispose the slider floating over the surface of the medium. The pressing mechanism includes an elastic body 56 composed of a plate spring that contacts the movable support part and elastically presses the movable support part.

Abstract: A slider tester includes a driving unit that rotates a test medium, a set plate that detachably supports a slider as a single body, and an investigating apparatus that is electrically connected to the slider supported by the set plate and investigates the characteristics of the slider. A movable support part 30 that tiltably supports the slider is provided on the set plate. There is also provided a pressing mechanism that elastically presses the slider via the movable support part toward a surface of the medium to dispose the slider floating over the surface of the medium. The pressing mechanism includes an elastic body 56 composed of a plate spring that contacts the movable support part and elastically presses the movable support part.

Abstract: A method of bonding and a bonding apparatus for a semiconductor chip that apply ultrasonic vibration to the semiconductor chip to bond the semiconductor chip to a substrate carry out leveling effectively at low cost and in a short time and can improve the bonding between the semiconductor chip and the substrate. In a positioning step, bumps of the semiconductor chip and pads of the substrate are positioned and placed in contact. In a leveling step, ultrasonic vibration of a first predetermined frequency is applied to the semiconductor chip to make the bumps of the semiconductor chip and the pads of a substrate rub against each other to level the bumps. In a bonding step, ultrasonic vibration of a second predetermined frequency that differs to the first predetermined frequency is applied to the semiconductor chip to bond the bumps and pads of the semiconductor chip and the substrate.

Abstract: The structure of mounting an electronic component on a circuit board is capable of securely flip-chip-bonding the electronic component having bumps, whose separations are very short, to the circuit board without displacement. The structure of mounting an electronic component on a circuit board is characterized in that bumps of the electronic component are respectively flip-chip-bonded to electrodes of the circuit board by applying ultrasonic vibrations to the electronic component, and that a center of each of the bumps is previously relatively displaced, with respect to a center of each of the electrodes in a width direction, in a direction parallel to a direction of the ultrasonic vibrations.

Abstract: Method for mounting an electronic component on a circuit board firstly flip-chip bonding positioning bumps of the electronic component to pads of the circuit board by applying ultrasonic vibrations to the electronic component. Bonding bumps, whose diameters are shorter than those of the positioning bumps and whose projecting lengths are shorter than those of the positioning bumps, of the electronic component are flip-chip bonded to electrodes of the circuit board by applying ultrasonic vibrations to the electronic element. In this manner, a center of each of the bonding bumps is previously relatively displaced, with respect to a center of each of the electrodes in a width direction, in a direction parallel to a direction to the ultrasonic vibrations.

Abstract: A method of assembling a carriage assembly is disclosed. The method is are capable of suppressing fluctuation in the crimped (deformed) states of spacer portions when suspensions are attached to carriage arms. The method aligns fitting holes 10a provided in carriage arms 10 with spacer holes 12b of suspensions 12. Then the method passes a ball 20 with a diameter equal to or greater than an inner diameter of the spacer holes 12b through the spacer holes 12b to crimp edge portions of the spacer holes 12b in spacer portions 12a and thereby attach the suspensions 12 to the carriage arms 10. While the ball 20 is being pressed and sandwiched from both sides of the spacer holes 12b by two pressure-applying members 40a, 40b an ultrasonic vibration is applied to the two pressure-applying members 40a, 40b, the two pressure applying members 40a, 40b are moved so as to pass the ball 20 through the spacer holes 12b.

Abstract: A slider tester includes a driving unit that rotates a test medium, a set plate that detachably supports a slider as a single body, and an investigating apparatus that is electrically connected to the slider supported by the set plate and investigates the characteristics of the slider. A movable support part 30 that tiltably supports the slider is provided on the set plate. There is also provided a pressing mechanism that elastically presses the slider via the movable support part toward a surface of the medium to dispose the slider floating over the surface of the medium. The pressing mechanism includes an elastic body 56 composed of a plate spring that contacts the movable support part and elastically presses the movable support part.

Abstract: A method of ultrasonic mounting can increase mounting efficiency by using high-frequency ultrasound and can also mount large semiconductor chips. The method ultrasonically bonds a semiconductor chip 52 to a substrate 50 using an ultrasonic mounting apparatus including a horn 15 that propagates ultrasonic vibration of an ultrasonic vibrator, the horn 15 being made of a ceramic that has a higher vibration propagation speed than metal. The method includes steps of disposing the substrate 50 on a stage 13, disposing the semiconductor chip 52 on the substrate 50, and placing the semiconductor chip 52 in contact with a convex part 15a provided on the horn 15 and applying ultrasonic vibration to bond the semiconductor chip 52 to the substrate 50.

Abstract: A method of ultrasonic mounting can increase mounting efficiency by using high-frequency ultrasound and can also mount large semiconductor chips. The method ultrasonically bonds a semiconductor chip 52 to a substrate 50 using an ultrasonic mounting apparatus including a horn 15 that propagates ultrasonic vibration of an ultrasonic vibrator, the horn 15 being made of a ceramic that has a higher vibration propagation speed than metal. The method includes steps of disposing the substrate 50 on a stage 13, disposing the semiconductor chip 52 on the substrate 50, and placing the semiconductor chip 52 in contact with a convex part 15a provided on the horn 15 and applying ultrasonic vibration to bond the semiconductor chip 52 to the substrate 50.

Abstract: A method of bonding and a bonding apparatus for a semiconductor chip that apply ultrasonic vibration to the semiconductor chip to bond the semiconductor chip to a substrate carry out leveling effectively at low cost and in a short time and can improve the bonding between the semiconductor chip and the substrate. In a positioning step, bumps of the semiconductor chip and pads of the substrate are positioned and placed in contact. In a leveling step, ultrasonic vibration of a first predetermined frequency is applied to the semiconductor chip to make the bumps of the semiconductor chip and the pads of a substrate rub against each other to level the bumps. In a bonding step, ultrasonic vibration of a second predetermined frequency that differs to the first predetermined frequency is applied to the semiconductor chip to bond the bumps and pads of the semiconductor chip and the substrate.

Abstract: A method and apparatus for assembling a carriage assembly attach suspensions to carriage arms without deformation and with higher accuracy than with the conventional art. Suspensions are placed on carriage arms by aligning engagement holes 10a provided in the carriage arms and spacer holes provided in spacer portions of the suspension. A bar-shaped operation member whose outer diameter is equal to or smaller than the inner diameter of the spacer holes is inserted into the spacer holes and longitudinal ultrasonic vibration is applied to the bar-shaped operation member to cause expanding and contracting motion in the radial direction of the spacer hole, so that when the diameter of the operation member expands, the operation member contacts edge portions of the spacer holes of the spacer portions and crimps the edge portions to fix the suspensions to the carriage arms.

Abstract: A method of ultrasonic mounting can increase mounting efficiency by using high-frequency ultrasound and can also mount large semiconductor chips. The method ultrasonically bonds a semiconductor chip 52 to a substrate 50 using an ultrasonic mounting apparatus including a horn 15 that propagates ultrasonic vibration of an ultrasonic vibrator, the horn 15 being made of a ceramic that has a higher vibration propagation speed than metal. The method includes steps of disposing the substrate 50 on a stage 13, disposing the semiconductor chip 52 on the substrate 50, and placing the semiconductor chip 52 in contact with a convex part 15a provided on the horn 15 and applying ultrasonic vibration to bond the semiconductor chip 52 to the substrate 50.

Abstract: A method of flip-chip mounting a semiconductor chip can carry out bonding at normal temperature and improves the positional accuracy of bonding. The method of flip-chip bonding a semiconductor chip 52 includes a step of providing a hardening trigger that is not heat to insulating adhesive 51 either before the semiconductor chip 52 is mounted on the substrate 50 or during bonding; and a step of bonding the bumps of the semiconductor chip to the pads of the substrate 50 by pressure welding or metal combining while hardening of the insulating adhesive 51 is progressing due to provision of the hardening trigger.