A jet soldering apparatus has a first housing; a first supply port provided on the first housing and configured to provide molten solder; a second housing; and a second supply port provided on the second housing and configured to provide the molten solder. The molten solder supplied from the first supply port and the molten solder supplied from the second supply port are mixed. The mixed molten solder is not separated from a substrate conveyed by a conveyance unit between the first supply port and the second supply port.

The invention relates to a method for operating a soldering system for selective wave soldering comprising at least one solder crucible, the solder crucible comprising a solder reservoir, a solder nozzle and a solder pump, the solder pump being designed to guide the liquid solder out from the solder reservoir through the solder nozzle for generating a standing wave from liquid solder. The invention relates, in particular, to a method for cleaning a solder nozzle comprising the following steps: conveying solder from the solder reservoir at a first pump capacity which is adjusted in such a way that a standing wave of liquid solder is generated at a solder level which is below an upper edge of the nozzle outlet of the solder nozzle; introducing a cleaning agent into the nozzle outlet of the solder nozzle; increasing the pumping capacity of the solder pump to a second pump capacity such that the cleaning agent flows over the upper edge of the nozzle such that the cleaning agent is guided to an outer side of the solder nozzle.

A jet solder bath for performing soldering by jetting molten solder to bring the molten solder into contact with a substrate is provided with a primary jet nozzle that jets the molten solder by a first jet pump, as a first jet nozzle, and a secondary jet nozzle, as a second jet nozzle, which is arranged at a downstream side of the primary jet nozzle along a carrying direction of the substrate and jets the molten solder by a second jet pump. The primary jet nozzle includes a first nozzle body, and a first solder-flow-forming plate that is provided at an upper end of the first nozzle body and has a plurality of jet holes, and the secondary jet nozzle includes a second nozzle body and a second solder-flow-forming plate that is provided at an upper end of the second nozzle body and has a plurality of jet holes.

A lead-free, antimony-free tin solder which is reliable at high temperatures and comprises up to 10 wt % Ag, up to 10 wt % Bi, up to 3 wt % Cu, other optional additives, balance tin, and unavoidable impurities.

A jet solder bath for performing soldering by jetting molten solder to bring the molten solder into contact with a substrate is provided with a primary jet nozzle that jets the molten solder by a first jet pump, as a first jet nozzle, and a secondary jet nozzle, as a second jet nozzle, which is arranged at a downstream side of the primary jet nozzle along a carrying direction of the substrate and jets the molten solder by a second jet pump. The primary jet nozzle includes a first nozzle body, and a first solder-flow-forming plate that is provided at an upper end of the first nozzle body and has a plurality of jet holes, and the secondary jet nozzle includes a second nozzle body and a second solder-flow-forming plate that is provided at an upper end of the second nozzle body and has a plurality of jet holes.

The invention relates to a method for operating a soldering system for selective wave soldering comprising at least one solder crucible, the solder crucible comprising a solder reservoir, a solder nozzle and a solder pump, the solder pump being designed to guide the liquid solder out from the solder reservoir through the solder nozzle for generating a standing wave from liquid solder. The invention relates, in particular, to a method for cleaning a solder nozzle comprising the following steps: conveying solder from the solder reservoir at a first pump capacity which is adjusted in such a way that a standing wave of liquid solder is generated at a solder level which is below an upper edge of the nozzle outlet of the solder nozzle; introducing a cleaning agent into the nozzle outlet of the solder nozzle; increasing the pumping capacity of the solder pump to a second pump capacity such that the cleaning agent flows over the upper edge of the nozzle such that the cleaning agent is guided to an outer side of the solder nozzle.

The invention relates to a soldering nozzle for the simultaneous selective wave soldering of at least two spaced-apart rows of solder joints in a soldering installation, with a base portion which can be arranged on a nozzle plate, and with a wave portion which forms the solder wave during operation and which has a peripheral wall having a free upper side, and with at least one separating strip which can be inserted into the wave portion and which can be wetted with solder, wherein the at least one separating strip is formed as a frameless separating strip. The invention also relates to a soldering installation having a nozzle plate and having at least one soldering nozzle.

A soldering nozzle (100) for selectively soldering assemblies by means of molten solder supplied through a soldering nozzle (100) from a solder bath. The soldering nozzle (100) is designed as a deep-drawn part. A method for the production of a soldering nozzle (100) is specified as well, including the provision of a blank (401); the drawing of the blank (401) through at least one female die (411, 421) by means of at least one male die (413, 422, 431) to produce an oblong shape (439) of locally annular or substantially annular cross-section, with a first end (436) corresponding to an action point of the male die (413, 422, 431) and a second end (437) corresponding to an introduction cross-section of the male die (413, 422, 431), the cross-section preferably increasing from the first end (436) towards the second end (437); and the formation of an opening (446) at the tip end (436).

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.

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.