A method of manufacturing a pallet for use during manufacture of a printed circuit board assembly includes determining optimal solder flow for establishing connections between lead pins of a plurality of pin-through-hole components arranged on a circuit board, designing a pallet to include geometries configured to provide the optimal solder flow when the pallet, supporting the circuit board thereon, is passed through a wave solder machine, and creating the pallet based on the design. Pallets configured for optimal solder flow and methods of manufacturing printed circuit board assemblies using such pallet are also provided.

A method for producing an electric circuit in which a contact carrier comprising a first contact area and a second contact area is provided. An insulating body is applied to the circuit carrier and at least partially covers the first contact area and the second contact area. The insulating body comprises cut-outs in regions both contact areas. A flowable electrical conducting medium is introduced into the insulating body.

A soldering structure configured for preventing solder overflow during soldering and a power module, may include a component to be soldered; and a metal layer having a bonding area, to which the component to be soldered is bonded by solder, and a groove portion formed around the bonding area.

A support substrate has first electric contacts in a front face. An electronic component is located above the front face of the support substrate and has second electric contacts facing the first electric contacts of the support substrate. An electric connection structure is interposed between corresponding first and second electric contacts of the support substrate and the electronic component, respectively. Each electric connection structure is formed by: a shim that is made of a first electrically conducting material, and a coating that is made of a second electrically conducting material (different from the first electrically conducting material). The coating surrounds the shim and is in contact with the corresponding first and second electric contacts of the support substrate and the electronic component.

Provided are a jet solder level confirmation jig and a method of handling the same, which allow the level of the jet wave of the molten solder to be accurately confirmed. A jet solder level confirmation jig is provided with a level confirmation unit for confirming a level of a jet wave of molten solder, a holding unit that holds the level confirmation unit, a notifying unit that notifies the level of the jet wave of the molten solder; and a bridge member having a length so as to be able to form a bridge in an upper part of a jet solder bath housed within a housing, the bridge member supporting the level confirmation unit in the upper part of the jet solder bath. The notifying unit is connected to a power supply unit of a jet soldering device.

Methods and apparatus for applying molten solder are disclosed. A system for applying solder to a workpiece includes a conveyor for moving a first workpiece along a machine direction, and a first selective soldering nozzle to apply solder to the first workpiece while the first workpiece is moving along the machine direction. The system can also include a flux application area to apply flux to bottoms of workpieces, a heating area to heat the bottoms of the workpieces, and a conveyor to convey the workpieces. The workpiece can constantly move through multiple areas, such as a flux application area, a heating area, and a selective soldering area. As such, two or more areas can operate on the workpiece simultaneously and while the workpiece is moving. The method includes applying solder from the first selective soldering nozzle to the first workpiece while the first workpiece is moving along the machine direction.

A reel for the purpose of winding a length of cable of optical fiber cable type includes a winding support for winding the length of cable, a retaining part suitable for retaining the length of cable wound around the winding support, a first attachment part for the purpose of attaching the reel to an edge of a circuit board such that the reel is positioned laterally with respect to the circuit board, and a second attachment part for the purpose of attaching the reel flat to a face of the circuit board.

An electronic device includes a circuit board and an electronic element. The circuit board includes a plate body and multiple through holes extending through the plate body. Each of the through holes has a first diameter. The electronic element includes multiple pins, each of which is inserted into a respective one of the through holes, is secured to the circuit board by a soldering process, and has a second diameter smaller than the first diameter of the respective one of the through holes. For each of the pins, a difference between the second diameter of the pin and the first diameter of the respective one of the through holes ranges from 0.4 mm to 0.6 mm. A method for manufacturing the electronic device is also provided.

A soldering apparatus has a soldering iron unit having a soldering tip for carrying out a soldering process to a printed circuit board, a heater unit for heating the soldering iron unit, and a gas supply device for operatively supplying a burning-assist gas to the soldering iron unit, when a cleaning process is carried out for the soldering iron unit. The cleaning process for the soldering iron unit is carried out when the soldering process to the printed circuit board is stopped. In the cleaning process, the soldering iron unit is heated by the heater unit and the burning-assist gas is supplied to the soldering iron unit, so that material attached to the soldering iron unit can be easily burnt out.

A component carrier which includes a stack having at least one electrically conductive layer structure and at least one electrically insulating layer structure, and electrically conductive wiring structures being part of the at least one electrically conductive layer structure, wherein a value of the passive intermodulation for signals propagating along the electrically conductive wiring structures is less than 153 dBc.