A welded member includes a hot dip Zn-based alloy coated steel sheet as a base material and has excellent corrosion resistance and weld bead shear strength. In the welded member in which a lower sheet and an upper sheet, which are hot dip Zn-based alloy coated steel sheets, are stacked and arc-welded together, a weld bead is formed so that a cross-sectional width W satisfies the following formula 2TW6T, and a blowhole occupancy Br represented by the following formula (2) becomes not more than 50%: Br=(di/L)100, where T represents a thickness of the hot dip Zn-based alloy coated steel sheet, di represents a length of an i-th blowhole observed in X-ray radiography, and L represents a length of the weld bead.

A method for the joining of ceramic pieces with a hermetically sealed joint comprising brazing a layer of joining material between the two pieces. The wetting and flow of the joining material is controlled by the selection of the joining material, the joining temperature, the joining atmosphere, and other factors. The ceramic pieces may be on a non-diffusable type, such as aluminum nitride, alumina, beryllium oxide, and zirconia, and the pieces may be brazed with an aluminum alloy under controlled atmosphere. The joint material is adapted to later withstand both the environments within a process chamber during substrate processing, and the oxygenated atmosphere which may be seen within the shaft of a heater or electrostatic chuck.

A method for the joining of ceramic pieces with a hermetically sealed joint comprising brazing a layer of joining material between the two pieces. The wetting and flow of the joining material is controlled by the selection of the joining material, the joining temperature, the joining atmosphere, and other factors. The ceramic pieces may be on a non-diffusable type, such as aluminum nitride, alumina, beryllium oxide, and zirconia, and the pieces may be brazed with an aluminum alloy under controlled atmosphere. The joint material is adapted to later withstand both the environments within a process chamber during substrate processing, and the oxygenated atmosphere which may be seen within the shaft of a heater or electrostatic chuck.

A welding system includes a welding power source configured to provide pulsed electropositive direct current (DCEP), a gas supply system configured to provide a shielding gas flow that is at least 90% argon (Ar), a welding wire feeder configured to provide tubular welding wire. The DCEP, the tubular welding wire, and the shielding gas flow are combined to form a weld deposit on a zinc-coated workpiece, wherein less than approximately 10 wt % of the tubular welding wire is converted to spatter while forming the weld deposit on the zinc-coated workpiece.

A reflow soldering apparatus, system, and method. The reflow soldering system may include a housing that is alterable between an open state and a closed state, the open state being used for loading and unloading of substrates and the closed state being used during operation. The system may also include a heating assembly located within the chamber and a cooling assembly that is spaced apart from the heating assembly. A support member may be included to support a substrate within the chamber. A first actuator unit may be operably coupled to either the heating and cooling assemblies jointly, or to the support member. Additionally, the system may include a control unit coupled to the first actuator unit to cause relative movement between the substrate and the heating and cooling assemblies. Thus, the substrate can move between the heating and cooling assemblies during the various stages of the reflow soldering process.

The provided relates to a method for preparing an anisotropic conductive adhesive for fine pitch and an anisotropic conductive adhesive for fine pitch prepared by the same method. Provided is a method for preparing an anisotropic conductive adhesive for a fine pitch including: (i) removing an oxide film of solder particles having self-fusion and self-orientation functions between metal terminals of a substrate by melting the solder particles at a predetermined temperature using a first reducing agent; (ii) removing moisture generated in step (i); and (iii) preparing an anisotropic conductive adhesive by mixing the solder particles from which the oxide film and the moisture are removed with a binder resin in steps (i) and (ii), in which step (iii) is performed in a state where a contact with oxygen is blocked.

A visible light laser system and operation for welding materials together. A blue laser system that forms essentially perfect welds for copper based materials. A blue laser system and operation for welding conductive elements, and in particular thin conductive elements, together for use in energy storage devices, such as battery packs.

A visible light laser system and operation for welding materials together. A blue laser system that forms essentially perfect welds for copper based materials. A blue laser system and operation for welding conductive elements, and in particular thin conductive elements, together for use in energy storage devices, such as battery packs.

A method for producing a welded blank (1) includes providing two precoated sheets (2), butt welding the precoated sheets (2) using a filler wire. The precoating (5) entirely covers at least one face (4) of each sheet (2) at the time of butt welding. The filler wire (20) has a carbon content between 0.01 wt. % and 0.45 wt. %. The composition of the filler wire (20) and the proportion of filler wire (20) added to the weld pool is chosen such that the weld joint (22) has (a) a quenching factor FT.sub.WJ: FT.sub.WJ?0.9FT.sub.BM?0, where FT.sub.BM is a quenching factor of the least hardenable substrate (3), and FT.sub.WJ and FT.sub.BM are determined: FT=128+1553?C+55?Mn+267?Si+49?Ni+5?Cr?79?Al?2?Ni.sup.2?1532?C.sup.2?5?Mn.sup.2?127?Si.sup.2?40?C?Ni?4?Ni?Mn, and (b) a carbon content C.sub.WJ<0.15 wt. % or, if C.sub.WJ?0.15 wt. %, a softening factor FA.sub.WJ such that FA.sub.WJ>5000, where FA=10291+4384.1?Mo+3676.9Si?522.64?Al?2221.2?Cr?118.11?Ni?1565.1?C?246.67?Mn.

Provided are a cleaning device and a method for cleaning a vulcanization mold. At the time of cleaning a molding surface of a vulcanization mold by irradiating with a laser beam from a laser head, an inert gas is supplied from a supply nozzle and an irradiation range of the molding surface irradiated with the laser beam is brought into an atmosphere of the inert gas.