A solder supply unit able to be attached to a solder cutting unit and is able to detached is provided. The solder supply unit includes a reel holder rotatably holding a reel of a tape-like solder material; and a guidance member guiding the tape-like solder material wound around the reel when the tape-like solder material is fed out. The guidance member includes an extension portion guiding a lower surface of the tape-like solder material along a feeding direction of the tape-like solider material; and an opening penetrating the extension portion in an up-down direction and extending toward an upstream side in the feeding direction from a downstream end of the guidance member. The opening is formed in the predetermined length in the feeding direction so that a holding member, which holds the tape-like solder material together with another holding member, is able to move in the feeding direction.

The present application relates to a stencil device (150) for simultaneous stencil printing of brazing material onto elevations, areas surrounding port openings, and a circumferential skirt (210) of a heat exchanger plate (200) wherein the stencil device (150) comprises an upper stencil having openings for applying brazing material to elevations and areas surrounding port openings of the heat exchanger plate (200) and a lower stencil printing stencil (150) having a large opening (190) for receiving the heat exchanger plate (200) and contacting an outer perimeter of the circumferential skirt (210) of the heat exchanger plate (200), wherein an inner surface (195) of the large opening (190) comprises brazing material exits (160) for applying brazing material to the circumferential skirts (195). Disclosed is also a method of such stencil printing and also the use of a stencil device for applying heat exchanger plates (200) with a brazing material.

A brazing system according to an embodiment of the present invention, which is for brazing an object to be bonded to a base material, comprises: a turntable provided with a reception part for receiving the base material and rotatable clockwise or counterclockwise; a base material supply device for supplying the base material to the reception part; a brazing filler metal supply device for supplying a brazing filler metal to an upper side of the base material; a first heating device for bonding the brazing filler metal to the base material; a bonding object supply device for supplying the object to be bonded to an upper side of the brazing filler metal bonded to the base material; a second heating device which is in contact with opposite sides of the base material to fix the base material and is provided with electrodes for supplying electric current to the base material so as to bond the object to be bonded to the base material; and a cooling device which comes into contact with the object to be bonded to cool the object to be bonded.

Solder supply device includes solder cup that is tubular and open at one end, nozzle section for ejecting solder from the solder cup, flange section that is fixedly provided on an outer circumferential section of the nozzle section and that is engaged inside of the solder cup, and inner tube an end of which holds the nozzle section and the other end of which extends from the opening of the solder cup; the flange section is formed from material that is elastically deformable and the flange section is engaged inside the cup with an outer edge section of the flange section in an elastically deformed state. The elastic force arising between the outer edge section of the flange section and the solder cup is smaller than the holding force of the nozzle section by the inner tube.

A soldering apparatus, that moves a jet nozzle while ensuring that molten solder does not spill to the outside of the jet nozzle, is provided. The soldering apparatus includes a solder tank storing the molten solder, a jetting mechanism including the jet nozzle and a pump, which pumps the molten solder stored in the solder tank, an XY-direction moving mechanism that moves the solder tank, and a control device that controls the acceleration and deceleration of the solder tank according to the height of the molten solder protruding upwards from a tip of the jet nozzle or the height of the molten solder protruding upwards from the tip of the jet nozzle according to the acceleration and deceleration of the solder tank.

A method for filling a through hole with solder includes mounting a substrate having a through hole formed therein on a permeable barrier layer having pores that enable gas to flow through the permeable barrier. A solder source is positioned over the through hole. Molten solder is delivered in the through hole with a positive pressure from the solder source such that gas in the through holes passes the permeable barrier while the molten solder remains in the through hole.

A device for assembling an element on a surface of a substrate by providing a solder-forming mass. The device has a means for moving the element and a measurement means. The means for moving the element includes a support and an element gripper member. The gripper member has a vertical axis that is perpendicular to the surface of the substrate and is mounted to move freely in translation on the support in a direction parallel to its vertical axis. The measurement means measures a variation of the position of the element in vertical translation.

A soldering device comprising: a first treatment part that sets a component having an electrode; a second treatment part separated by an opening-closing unit, the second treatment part sending the component on to a third treatment part; the third treatment part separated by an opening-closing unit, the third treatment part causing the component to contact an organic fatty-acid-containing solution and move horizontally; a fourth treatment part having a unit for moving the component to a space portion and causing molten solder to adhere to the electrode; and a unit for removing excess molten solder; a fifth treatment part for horizontally moving the component moved downward by the fourth treatment part; a sixth treatment part separated by an opening-closing unit, the sixth treatment part sending the component on to a seventh treatment part; and the seventh treatment part separated by an opening-closing unit, the seventh treatment part taking out the component.

Methods for die attachment of multichip and single components including flip chips may involve printing a sintering paste on a substrate or on the back side of a die. Printing may involve stencil printing, screen printing, or a dispensing process. Paste may be printed on the back side of an entire wafer prior to dicing, or on the back side of an individual die. Sintering films may also be fabricated and transferred to a wafer, die or substrate. A post-sintering step may increase throughput.

An electronic component is mounted on a substrate according to a mounting mode which is set in advance in the following mounting informationwhen component mounting work is performed. In the mounting information, any one of a first mounting mode in which an electronic component is transferred and mounted to a mounting position which is corrected based on a positional-shift amount between a position of a printed solder and a position of an electrode and a second mounting mode in which the electronic component is transferred and mounted to the mounting position by considering only the position of the electrode as a reference, is set as a mounting mode for performance for each electronic component mounting device.