A method for interconnecting multiple components of a head-gimbal assembly with a solder joint, including the steps of positioning a first component adjacent to and at an angle relative to a second component to provide a connection area between the first and second components, dispensing a solder sphere to a capillary tube having tapered walls, wherein the capillary tube is positioned with an exit orifice above the connection area between the first and second components, pressurizing the capillary tube until a predetermined pressure is reached, applying a first laser pulse to the solder sphere to liquefy the solder sphere until it falls from the exit orifice, waiting for a predetermined time period after the liquefied solder sphere has exited the exit orifice of the capillary tube, and applying a second laser pulse to reflow the solder sphere to create the solder joint between the first and second components.

A method and a device for establishing a wire connection between a first contact surface and at least one further contact surface. A contact end of a wire is positioned in a contact position relative to the first contact surface with a wire guiding tool. Subsequently, a mechanical, electrically conductive connection is established between the first contact surface and the contact end with a first solder material connection, and subsequently the wire guiding tool is moved to the further contact surface thus forming a wire section and establishing a further mechanical, electrically conductive connection between the wire section end and the further contact surface with a further solder material connection.

Stencil frames for tensioning stencils of an angular shape are provided. The stencil frame comprises corner elements (2), edge elements (1), fastening elements (13) and tensioning devices with a tensioning device being associated with each edge element (1). The corner elements (2) each have two, mutually perpendicular, guiding profiles (12) which joined at an intersection of their axes and the edge elements (1) each have a uniaxial reception profile (11). Each reception profile (11) is connectable to two guiding profiles (12) by loose fit. Each tensioning device has at least one elastic element (5) and connects between two neighbouring corner elements (2). A line of force exerted by each tensioning device is parallel to the axis of its corresponding reception profile (11).

A system of producing metal cored solder structures on a substrate includes: a decal, a carrier, and receiving elements. The decal includes one or more apertures each of which is tapered from a top surface to a bottom surface thereof. The carrier is positioned beneath the bottom of the decal and includes cavities in a top surface. The cavities are located in alignment with the apertures of the decal. The decal is positioned on the carrier having the decal bottom surface in contact with the carrier top surface to form feature cavities defined by the decal apertures and the carrier cavities. The feature cavities are shaped to receive one or more metal elements and are configured for receiving molten solder cooled in the cavities. The decal is separable from the carrier to partially expose metal core solder contacts. The receiving elements receive the metal core solder contacts thereon.

Provided is an apparatus for mounting a conductive ball, and more particularly, an apparatus for mounting a conductive ball, whereby defects during a process of mounting a conductive ball on a substrate by using a mounting hole formed in a mask may be prevented, and a conductive ball having a small size may also be effectively mounted on the substrate. According to the apparatus for mounting a conductive ball, a process of mounting a conductive ball may be performed by preventing deformation of a mask, thus achieving a high quality of the process without missing any conductive balls.

Provided is a method of mounting a conductive ball, and more particularly, a method of mounting a conductive ball, whereby defects during a process of mounting a conductive ball on a substrate by using a mounting hole formed in a mask may be prevented, and a conductive ball having a small size may also be effectively mounted on the substrate. According to the method of mounting a conductive ball, a process of mounting a conductive ball may be performed by preventing deformation of a mask, thus achieving a high quality of the process without omitting any conductive balls.

An applying method includes the following steps. Firstly, a conductive adhesive including a plurality of conductive particles and an insulating binder is provided. Then, a carrier plate is provided. Then, a patterned adhesive is formed on the carrier plate by the conductive adhesive, wherein the patterned adhesive includes a first transferring portion. Then, a manufacturing device including a needle is provided. Then, the needle of the manufacturing device is moved to contact the first transferring portion. Then, the transferring portion is transferred to a board by the manufacturing device.

A solder member mounting method includes providing a substrate having bonding pads formed thereon, detecting a pattern interval of the bonding pads, selecting one of solder member attachers having different pattern intervals from each other, such that the one selected solder member attacher of the solder member attachers has a pattern interval corresponding to the detected pattern interval of the bonding pads, and attaching solder members on the bonding pads of the substrate, respectively, using the one selected solder member attacher.

An ejector for jetting droplets of viscous media onto a substrate is disclosed. The ejector comprises a jetting nozzle having a nozzle space and a nozzle outlet, and an impacting device for impacting a volume of the viscous medium in the nozzle space such that droplets of viscous medium is jetted from the nozzle space through the nozzle outlet towards the substrate. The ejector also comprise a sensor arrangement arranged after the jetting nozzle in the jetting direction, wherein the sensor arrangement is adapted to detect a jetted droplet of viscous medium passing thereby.

Methods for depositing material on a chip include forming a mold layer. The mold layer includes one or more openings over respective contact areas, each of the one or more openings having an upper volume and a lower volume. The upper volume has a smaller diameter than a diameter of the lower volume. Each contact area is within the respective lower volume. A material is injected into the one or more openings under pressure.