A heat transfer device for thermal coupling of a component to be soldered, having a heat source and/or a heat sink in a soldering machine, with at least one base plate which is designed to be in thermal contact at least with the heat source and/or the heat sink. The base plate has a plurality of contact units having a respective contact surface, where the contact surfaces are thermally contactable to the components. The contact units are designed in such a way that the relative distances between the contact surfaces and the surface of the base plate facing the component are changeable. A soldering device, in particular a vacuumable soldering device, is provided having at least one such heat transfer device.

A method for creating a bonded zinc-coated structure is provided. In another aspect, a sheet metal joining system includes a heated roller contacting a sheet metal workpiece to braze together zinc-based coatings. A further aspect employs a zinc coated metal sandwich including a core having peaks and valleys.

Embodiments of a thermal compression bonding (TCB) process cooling manifold, a TCB process system, and a method for TCB using the cooling manifold are disclosed. In some embodiments, the cooling manifold comprises a pre-mixing chamber that is separated from a mixing chamber by a baffle. The baffle may comprise at least one concentric pattern formed through the baffle such that the primary cooling fluid in the pre-mixing chamber is substantially evenly distributed to the mixing chamber. The pre-mixing chamber may be coupled to a source of primary cooling fluid. The mixing chamber may have an input configured to accept the primary cooling fluid and an output to output the primary cooling fluid.

Systems and methods are disclosed for integrated compressed air cooling for welding systems. In particular, the disclosed systems and methods may employ compressed air to implement one or more welding processes (e.g., a gouging or cutting processes), with the compressed air being conveyed through such welding systems. In some examples, the compressed air is routed within the welding system to provide cooling for one or more components therein. For instance, components such as power conversion circuitry may heat up during the welding process. Routing compressed air to or near the components will introduce relatively cool air to the environment. As the passing compressed air heats in response to interaction with the heated components, heat is drawn from the components and/or the nearby environment.

A soldering jig for double-faced cooling power modules is provided. The soldering jig prevents thermal deformation of a substrate during a soldering process. The soldering jig is used to fix the position of an upper substrate and a lower substrate when a semiconductor chip is disposed and soldered between the upper and lower substrates. The soldering jig includes a lower jig plate that is disposed under the lower substrate and fixes the position of lower substrate, an upper jig plate that is disposed over the upper substrate and compresses the upper substrate toward the lower substrate. Additionally, a connector which couples the lower jig plate and the upper jig plate, and an insert is installed on the connector and is disposed between the upper substrate and the lower substrate to maintain a constant distance between the upper substrate and the lower substrate during a soldering process.

Provided are a soldering apparatus that allows a gasket to be easily attached to and detached from the soldering apparatus, and a method of fixing the gasket to the soldering apparatus. The soldering apparatus includes: a furnace body; a gasket that is provided to at least a part of the furnace body, and that seals the furnace body; and a push rivet that fixes the gasket in an attachable/detachable manner to the furnace body.

Methods and associated structures of forming a package structure including forming a low melting point solder material on a solder resist opening location of an IHS keep out zone, forming a sealant in a non SRO keep out zone region; attaching the IHS to the sealant, and curing the sealant, wherein a solder joint is formed between the IHS and the low melting point solder material.

An arrangement includes a chamber, a heating element arranged in the chamber, wherein the heating element, when a first connection partner with a pre-connection layer formed thereon is arranged in the chamber, is configured to heat the first connection partner and the pre-connection layer, thereby melting the pre-connection layer, and a cooling trap. During the process of heating the first connection partner with the pre-connection layer formed thereon, the cooling trap has a temperature that is lower than the temperature of all other components of or in the chamber such that liquid evaporating from the pre-connection layer is attracted by and condenses on the cooling trap.

A radiative heat collective bonder or gangbonder for packaging a semiconductor die stack is provided. The bonder generally includes a shroud positioned at least partially around the die stack and a radiative heat source positioned inward of the shroud and configured to emit a radiative heat flux in a direction away from the shroud. The bonder may further include a bondhead configured to contact the backside of the topmost die in the die stack and optionally include another bondhead configured to contact a substrate beneath the die stack. The radiative heat source may be configured to direct the radiative heat flux to at least a portion of the die stack to reduce a vertical temperature gradient in the die stack. One or both of the bondheads may be configured to concurrently direct a conductive heat flux into the die stack.

A space-based circuit-replacing robotic system and method include a satellite grasper configured to grasp the satellite having a printed circuit onto which an integrated circuit is soldered and the integrated circuit is to be replaced; an access mechanism configured to remove the printed circuit and/or to provide access to the printed circuit; a printed circuit orientation device configured to orient a printed circuit such that sunlight is incident on the printed circuit; one or more temperature sensors configured to measure a temperature of the solder on the printed circuit; a processor configured to adjust a rate of heating to match a desired heating rate; a circuit grasping device configured to position the circuit for replacement; and an optical shield that is configured to be adjusted to allow light to pass substantially only to a desired area of the printed circuit.