A substantially tubular iron tip (5) that can be heated and that is extended vertically and a solder piece supply portion that supplies a first solder piece (Wh1) and a second solder piece (Wh2) in which a layer of a flux (72) is provided within a tubular solder layer in this order from above into the iron tip are provided, within the iron tip, the solder pieces are erected such that on the first solder piece, the second solder piece rides and the heat of the iron tip is used to melt the first solder piece and the second solder piece such that the molten solder is supplied downward. In this way, it is possible to more reliably heat and melt the solder pieces in a posture in which they are erected within the iron tip.

A substantially tubular iron tip (5) that can be heated and that is extended vertically and a solder piece supply portion that supplies a first solder piece (Wh1) and a second solder piece (Wh2) in which a layer of a flux (72) is provided within a tubular solder layer in this order from above into the iron tip are provided, within the iron tip, the solder pieces are erected such that on the first solder piece, the second solder piece rides and the heat of the iron tip is used to melt the first solder piece and the second solder piece such that the molten solder is supplied downward. In this way, it is possible to more reliably heat and melt the solder pieces in a posture in which they are erected within the iron tip.

A solder processing method according to one or more embodiments may include: sequentially supplying at least two solder pieces into a substantially tubular iron tip that is extended vertically, such that the at least two solder pieces are erected within the iron tip in such a manner that on the solder piece which is first supplied, the solder piece which is subsequently supplied rides; and heating the substantially tubular iron tip in a state where the at least two solder pieces are erected within the iron tip in such a manner that on the solder piece which is first supplied, the solder piece which is subsequently supplied rides, to melt the flux to be flown out from at least one of the at least two solder pieces to a space between an inner wall of the iron tip and the at least two solder pieces.

A solder processing method according to one or more embodiments may include: sequentially supplying at least two solder pieces into a substantially tubular iron tip that is extended vertically, such that the at least two solder pieces are erected within the iron tip in such a manner that on the solder piece which is first supplied, the solder piece which is subsequently supplied rides; and heating the substantially tubular iron tip in a state where the at least two solder pieces are erected within the iron tip in such a manner that on the solder piece which is first supplied, the solder piece which is subsequently supplied rides, to melt the flux to be flown out from at least one of the at least two solder pieces to a space between an inner wall of the iron tip and the at least two solder pieces.

A brazing apparatus to join a first component and a second component includes a heating element configured to melt a ring located at a joint between the first component and the second component, and a probe configured to contact the ring. A position of the probe is biased toward the ring. The probe is installed at a probe support. The probe is movable along a probe central axis relative to the probe support. A sensor is operably connected to the probe and is configured to determine movement of the probe along the probe central axis. The movement of the probe is indicative of melting of the ring.

A resistance soldering apparatus suited for soldering an electrical terminal to a glass surface and a method of using such an apparatus is described herein. The resistance soldering apparatus includes an electrode having a distal tip and an electrical terminal having a first major surface in which an indentation is defined and a second major surface opposite the first major surface on which a layer of a solder composition is disposed. The indentation is configured to receive the distal tip of the electrode. The distal tip of the electrode is placed within the indentation and an electrical current is passed through the electrode and the electrical terminal, The electrical current is sufficient to heat the electrode and melt the solder composition on the second major surface.

A smart soldering iron tip of a handheld soldering iron comprises a hollow cylindrical base; a pointed distal end; and a proximal end with an ID feedback device, which when read provides authentication information on the smart soldering iron tip.

A smart soldering iron tip of a handheld soldering iron comprises a hollow cylindrical base; a pointed distal end; and a proximal end with an ID feedback device including a conductive material coating, which when read provides authentication information on the smart soldering iron tip.

A smart soldering iron tip of a handheld soldering iron comprises a hollow cylindrical base; a pointed distal end; and a proximal end with an ID feedback device including a conductive material coating, which when read provides authentication information on the smart soldering iron tip.

A brazing system has a first gas source, a second gas source, an enclosure, a brazing torch, and a control system configured to control a ratio of the first gas source and the second gas source.