Abstract: A solder joint manufactured of an alloy essentially composed of 0.01-7.6 wt % Cu, 0.001-6 wt % Ni, and the remaining of Sn. Each of Cu and Ni has a maximum concentration range. The lower limit of the range of Ni is 0.01 wt % and preferably 0.03 wt %. The upper limit of the range of Ni is 0.3 wt % and preferably 0.1 wt %. The lower limit of the range of Cu is 0.1 wt % and preferably 0.2 wt %. The upper limit of the range of Cu is 7 wt % and preferably 0.92 wt %. The invention includes the solder joint essentially having these compositions.

Abstract: Provided is an apparatus for feeding wire solder with high tensile strength and pull cut resistance. The wire solder has an extended wire solder and a core wire having a higher tensile strength than the wire solder. The apparatus for feeding the wire solder comprises a wire solder storage section where the wire solder with a core wire is stored and a core wire rewinding member that takes up an end of the core wire to rewind the core wire. While the core rewinding member is rotated to rewind the core wire, the single or multiple strands of solder are heated to perform soldering at the location of soldering upstream of the core wire rewinding member.

Abstract: Disclosed herein are a flux and a soldering paste based on the flux. The flux is free from a change in viscosity with age, “skinned surface,” and “rough and crumbling,” and is excellent in printability and solderability. The flux contains, as elements, a resin, a thixo agent, an activator, a solvent and glucopyranosylamine type nanotube. The soldering paste further contains a solder powder. Preferably, the solder powder is free from lead.

Abstract: The present invention provides a lead-free solder alloy having high reliability and excellent solder bonding properties and suited for the mounting of micronized electronic components at low cost. The lead-free solder alloy according to the present invention has a composition containing 0.5 to 1.5 wt % of Ag, 0.3 to 1.5 wt % of Cu, 0.01 to 0.2 wt % of Ni, 1.0 wt % or less of Ga, and the balance being Sn and unavoidable impurities.

Abstract: A solder alloy may include a Sn—Cu hypereutectic area having Cu in the amount of up to 7.6 weight percent, from 0.006 to 0.5 weight percent of Al, Al2O3, or a combination thereof.

Abstract: A method by which the amount of nickel contained in an alloy having a composition represented by Sn—X—Ni can be regulated. The method of nickel concentration regulation comprises adding phosphorus to Sn—X—Ni in a molten state (wherein X is one or more elements selected from the group consisting of Ag, Zn, Cu, Bi, Au, Ti, Ge, Ga, Si, and Ce), holding the mixture at 250-400° C., and removing the resultant dross floating on the surface of the liquid phase and containing a P—Ni compound and a P—Sn—Ni compound. An example of X is copper, and the content thereof may be 0.3-5 wt %. The phosphorus may be added in the state of a Sn—P alloy. The upper limit of the amount of the phosphorus to be added may be about half the nickel amount in terms of atomic amount.

Abstract: Provided is a solder with high tensile strength and pull cut resistance. The wire solder has an extended wire solder and a core wire having a higher tensile strength than the wire solder. The wire solder has a single or multiple strands bound together. The wire solder is supplied from upstream of a location of soldering while the core wire is rewound under tension at a location downstream of the location of soldering.

Abstract: Provided is an apparatus for feeding wire solder with high tensile strength and pull cut resistance. The wire solder has an extended wire solder and a core wire having a higher tensile strength than the wire solder. The apparatus for feeding the wire solder comprises a wire solder storage section where the wire solder with a core wire is stored and a core wire rewinding member that takes up an end of the core wire to rewind the core wire. While the core rewinding member is rotated to rewind the core wire, the single or multiple strands of solder are heated to perform soldering at the location of soldering upstream of the core wire rewinding member.

Abstract: A granulation method for granulating a (CuX)6Sn5 compound by passing a composition comprising a (CuX)6Sn5 compound and tin through a multi-perforated plate to granulate the (CuX)6Sn5 compound wherein X represents an element which is solved in Cu but forms a precipitate with Sn.

Abstract: An apparatus for depositing and separating excess copper dissolved in molten lead-free solder containing tin as the main element is provided. An apparatus 1 deposits excess copper in the molten lead-free solder as an intermetallic compound and separates it from the molten solder. The apparatus includes a deposition bath 2 for causing an intermetallic compound in the molten solder, a metal added from the outside and copper in the molten solder to be deposited, a granulation bath 4 including plates 31 32 and 33 for allowing the molten solder to pass through the plates to merge the intermetallic compounds into particles having a larger diameter, and a separation bath 5 for causing the enlarged intermetallic compounds to precipitate and separate in the molten solder.

Abstract: Provided is a wire solder with high tensile strength and pull cut resistance. An apparatus for feeding the wire solder is also provided. The wire solder has an extended wire solder and a core wire having a higher tensile strength than the wire solder. The core wire is made of thermosetting resin or Joulean heat generating material. The wire solder has a single or multiple strands bound together. The wire solder is supplied from upstream of a location of soldering while the core wire is rewound under tension at a location downstream of the location of soldering. The apparatus for feeding the wire solder comprises a wire solder storage section where the wire solder with a core wire is stored and a core wire rewinding member that takes up an end of the core wire to rewind the core wire. While the core rewinding member is rotated to rewind the core wire, the single or multiple strands of solder are heated to perform soldering at the location of soldering upstream of the core wire rewinding member.

Abstract: Disclosed herein are a flux and a soldering paste based on the flux. The flux is free from a change in viscosity with age, “skinned surface,” and “rough and crumbling,” and is excellent in printability and solderability. The flux contains, as elements, a resin, a thixo agent, an activator, a solvent and glucopyranosylamine type nanotube. The soldering paste further contains a solder powder. Preferably, the solder powder is free from lead.

Abstract: Lead-free solder is replenished to a solder bath to receive a work having copper, the work to be processed subsequent to a soldering process using an air knife or a die. The replenished lead-free solder includes Sn as a major composition and at least 0.01 to 0.5 mass percent Ni. By replenishing the lead-free solder having the above composition, the density of the solder bath, being sharply changed for using one of a HASL device and a die, is quickly restored back to within an appropriate range.

Abstract: A method by which the amount of nickel contained in an alloy having a composition represented by Sn—X—Ni can be regulated. The method of nickel concentration regulation comprises adding phosphorus to Sn—X—Ni in a molten state (wherein X is one or more elements selected from the group consisting of Ag, Zn, Cu, Bi, Au, Ti, Ge, Ga, Si, and Ce), holding the mixture at 250-400° C., and removing the resultant dross floating on the surface of the liquid phase and containing a P—Ni compound and a P—Sn—Ni compound. An example of X is copper, and the content thereof may be 0.3-5 wt %. The phosphorus may be added in the state of a Sn—P alloy. The upper limit of the amount of the phosphorus to be added may be about half the nickel amount in terms of atomic amount.

Abstract: A solder joint manufactured of an alloy essentially composed of 0.01-7.6 wt % Cu, 0.001-6 wt % Ni, and the remaining of Sn. Each of Cu and Ni has a maximum concentration range. The lower limit of the range of Ni is 0.01 wt % and preferably 0.03 wt %. The upper limit of the range of Ni is 0.3 wt % and preferably 0.1 wt %. The lower limit of the range of Cu is 0.1 wt % and preferably 0.2 wt %. The upper limit of the range of Cu is 7 wt % and preferably 0.92 wt %. The invention includes the solder joint essentially having these compositions.

Abstract: An apparatus for depositing and separating excess copper dissolved in molten lead-free solder containing tin as the main element is provided. An apparatus 1 deposits excess copper in the molten lead-free solder as an intermetallic compound and separates it from the molten solder. The apparatus includes a deposition bath 2 for causing an intermetallic compound in the molten solder, a metal added from the outside and copper in the molten solder to be deposited, a granulation bath 4 including plates 31 32 and 33 for allowing the molten solder to pass through the plates to merge the intermetallic compounds into particles having a larger diameter, and a separation bath 5 for causing the enlarged intermetallic compounds to precipitate and separate in the molten solder.

Abstract: Lead-free solder is replenished to a solder bath to receive a work having copper, the work to be processed subsequent to a soldering process using an air knife or a die. The replenished lead-free solder includes Sn as a major composition and at least 0.01 to 0.5 mass percent Ni. By replenishing the lead-free solder having the above composition, the density of the solder bath, being sharply changed for using one of a HASL device and a die, is quickly restored back to within an appropriate range.

Abstract: The purpose of the present invention is to separate excess coppers leached out in a lead-free solder bath and recover tin with high efficiency. An element X for forming a (CuX)6Sn5 compound between copper and tin in molten lead-free solders is added to separate out a (CuX)6Sn5 compound. Tin is recovered by binding the (CuX)6Sn5 compound by passing thereof through a multi-perforated plate, further generating swirling currents to precipitate and separate the bound (CuX)6Sn5 compounds and removing thereof.

Abstract: The purpose of the present invention is to separate excess coppers leached out in a lead-free solder bath and recover tin with high efficiency. An element X for forming a (CuX)6Sn5 compound between copper and tin in molten lead-free solders is added to separate out a (CuX)6Sn5 compound. Tin is recovered by binding the (CuX)6Sn5 compound by passing thereof through a multi-perforated plate, further generating swirling currents to precipitate and separate the bound (CuX)6Sn5 compounds and removing thereof.

Abstract: The purpose of the present invention is to separate excess coppers leached out in a lead-free solder bath and recover tin with high efficiency. An element X for forming a (CuX)6Sn5 compound between copper and tin in molten lead-free solders is added to separate out a (CuX)6Sn5 compound. Tin is recovered by binding the (CuX)6Sn5 compound by passing thereof through a multi-perforated plate, further generating swirling currents to precipitate and separate the bound (CuX)6Sn5 compounds and removing thereof.