A flux unit includes a flux supply device configured to eject flux to a storage tray, an ejection port configured to eject the flux, and an ejection port moving device configured to move the ejection port in the radial direction of the storage tray. By this, the flux is ejected in a wide range in the radial direction of the storage tray. Also, the storage tray is rotated by a tray rotation device. Thus, the film thickness of the flux ejected in the wide range of the storage tray is adjusted by a squeegee all at once. Thus, the time required for adjusting the film thickness of the flux can be reduced.

A semiconductor fabrication apparatus has a transfer plate having a plurality of transfer pins to transfer a flux onto a plurality of lands on a semiconductor substrate, a holder movable with the transfer plate, to hold the transfer plate, a positioning mechanism to perform positioning of the holder so that the plurality of lands and the respective transfer pins contact each other; and a pitch adjuster to adjust a pitch of at least part of the plurality of transfer pins.

Methods for refurbishing a circuitry device are disclosed. The methods described herein include applying a first flux to solder contacts connecting a first member of a circuitry device to a second member of the circuitry device; performing a first setting process on the circuitry device with the first flux; applying a second flux to the solder contacts of the circuitry device; performing a second setting process on the circuitry device; and reflowing the solder contacts.

The flux according to the present invention includes a fatty acid amide; a first solvent having a temperature, at which its mass measured by thermogravimetry at a nitrogen flow rate of 0.2 to 0.3 L per minute and a temperature increase rate of 10 C. per minute becomes zero, of from 180 C. to lower than 260 C.; and a second solvent having a temperature, at which its mass measured by thermogravimetry at a nitrogen flow rate of 0.2 to 0.3 L per minute and a temperature increase rate of 10 C. per minute becomes zero, of from 100 C. to lower than 220 C. The flux has a content of the first solvent that is lower than a content of the second solvent. The flux does not include reducing agents for reduction removal of surface oxide films of solder, and does not include activators for improving reducibility.

An apparatus includes a fin pack of parallel plates that protrude from a base, a lid attachable to the fin pack opposite the base, and a brazing material painted onto the lid only in a plurality of wettable regions. The lid is positioned against the fin pack, opposite the base, with portions of the plurality of regions contacting edges of the parallel plates. The lid is brazed to the fin pack without intrusion of the brazing material between the parallel plates. This is accomplished by obtaining a lid to be attached to a fin pack of parallel plates that protrude from a base, painting the lid with the brazing material only in a plurality of wettable regions, positioning the lid against the fin pack, opposite the base, with portions of the plurality of regions contacting edges of the parallel plates, and brazing the lid to the fin pack.

A method for manufacturing a heat exchanger (1) includes joining an inner fin (3) to a hollow structure (20) formed from at least two clad plates (200a, 200b) by heating and brazing a filler metal layer (B). Each clad plate has a core layer (A) composed of an aluminum alloy that contains Mg: 0.40-1.0 mass %. The filler metal layer is composed of an aluminum alloy that contains Si: 4.0-13.0 mass %, and further contains Li: 0.0040-0.10 mass %, Be: 0.0040-0.10 mass %, and/or Bi: 0.01-0.30 mass %. The inner fin is composed of an aluminum alloy that contains Si: 0.30-0.70 mass % and Mg: 0.35-0.80 mass %. A flux (F) that contains cesium (Cs) is applied along a contact part (201), and the vicinity thereof, of the at least two clad plates prior to the heating. A heat exchanger (1) may be manufactured according to this method.

An apparatus, material and method for forming a brazing sheet has a composite braze liner layer of low melting point aluminum alloy and 4000 series braze liner. The low melting point layer of the composite braze liner facilitates low temperature brazing and decrease of the diffusion of magnesium from the core into the composite braze liner. The reduction of magnesium diffusion also lowers the formation of associated magnesium oxides at the braze joint interface that are resistant to removal by Nocolok flux, thereby facilitating the formation of good brazing joints through the use of low temperature controlled atmosphere brazing (CAB) and Nocolok flux. The apparatus also enables the production of brazing sheet materials with high strength and good corrosion property.

The invention relates to a process to connect, by soldering, at least one electronic component (104, 204, 304, 404, 504) with a mounting plate (100, 200, 300, 400, 500), the mounting plate having at least one mounting plate contact surface (102, 202, 302, 402, 502) and the at least one electronic component having at least one component contact surface (105) corresponding to it, the at least one mounting plate contact surface being surrounded by a solder resist layer (101, 201, 301, 401, 501) that borders the at least one mounting plate contact surface, the process having the following steps: a) Applying solder paste (106, 206, 306, 406, 506) onto at least areas of the solder resist layer (101, 201, 301, 401, 501), minimally overlapping with the mounting plate contact surface (102, 202, 302, 402, 502) adjacent to the solder resist layer, b) Equipping the mounting plate with the at least one electronic component (104, 204, 304, 404, 504), the at least one component contact surface (105) at least partly covering the at least one mounting plate contact surface (102, 202, 302, 402, 502) corresponding to it; and c) Heating the solder paste (106, 206, 306, 406, 506) to produce a soldered connection between the mounting plate and the at least one component.

The present invention relates to a method for producing a soldered product by which soldering can be accomplished without using a jig. The method for producing a soldered product of the present invention comprises: a provision step of providing a solder and a temporary fixing agent for temporarily fixing the solder; a temporary fixing step of temporarily fixing the solder to a soldering target with the temporary fixing agent; a vaporization step of placing the soldering target with the solder temporarily fixed thereto in a vacuum or heating the soldering target with the solder temporarily fixed thereto to a predetermined temperature lower than the melting temperature of the solder, to vaporize the temporary fixing agent in order to form gaps between the solder and the soldering target; a reduction step, performed concurrently with or after the vaporization step, of reducing, with a reducing gas at a predetermined temperature lower than the melting temperature of the solder, the solder and the soldering target left in the vaporization step; and a solder melting step, performed after the reduction step, of heating the soldering target to a predetermined temperature equal to or higher than the melting temperature of the solder to melt the solder.

Implementations of the disclosure are directed to a lead-free mixed solder powder paste suitable for low temperature to middle temperature soldering applications. The lead-free solder paste may consist of: an amount of a first solder alloy powder between 44 wt % and 83 wt %, the first solder alloy powder comprising Sn; an amount of a second solder alloy powder between 5 wt % to 44 wt %, the second alloy powder comprising Sn, where the first solder alloy powder has a liquidus temperature lower than a solidus temperature of the second solder alloy powder; and a remainder of flux. The solder paste may be used for reflow at a peak temperature below the solidus temperature of the higher solidus temperature solder powder but above the melting temperature of the lower solidus temperature one.