A stretchable mounting board that includes: a stretchable substrate; a mounting electrode portion on a main surface side of the stretchable substrate and containing a conductive filler and a resin; a solder portion connected to the mounting electrode portion; and an electronic component electrically connected to the mounting electrode portion with the solder portion interposed therebetween. The mounting electrode portion has a first main surface on a stretchable substrate side thereof, a second main surface on a solder portion side thereof, a first region including the first main surface, and a second region including the second main surface, and wherein, in a cross-section along a thickness direction of the mounting electrode portion passing through the first region and the second region, a sectional area of the conductive filler in the second region is larger than a sectional area of the conductive filler in the first region.

Some embodiments provide a novel surface-mount technology (SMT) printed circuit board (PCB) assembly. The SMT PCB assembly includes at least a pair of adjacent conductive pads with a small gap between them. During the development phase of the SMT PCB assembly, the small gap between the adjacent conductive pads, as well as some of the adjacent portions of the conductive pads, are covered with solder mask. An SMT component (e.g., a zero-ohm resistor) may then be mounted to the SMT PCB assembly through the exposed portions of the conductive pads. During the production phase, however, the solder mask is revised to cover the far sides of the conductive pads, which results in the adjacent portions of the conductive pads being exposed. As such, a solder jumper can easily be created during the production phase by connecting the two conductive pads using solder paste.

A power semiconductor substrate comprising an insulating planar base, at least one conductor track and at least one contact area as part of the conductor track, wherein a layer of a metallic material is disposed on the contact area by means of pressure sintering. The associated method comprises the steps of: producing a power semiconductor substrate that includes a planar insulating base, conductor tracks and contact areas; arranging a pasty layer, composed of a metallic material and a solvent, on at least one contact area of the power semiconductor substrate; and applying pressure to the pasty layer.

A method of applying viscous media on a substrate is disclosed. In the method, the substrate is provided, which is arranged for mounting of electronic components thereon. Further, flux is provided on a deposit of solder paste, which deposit is arranged at a predetermined position on the substrate. The flux is provided by a non-contact dispensing process, such as jetting. By providing flux on the deposit prior to reflow, the risk of quality related issues, such as e.g. graping, advantageously is reduced.

A stretchable mounting board that includes a mounting electrode section electrically connected to stretchable wiring, and solder electrically connected to the mounting electrode section. The mounting electrode section has a first electrode layer on a side thereof facing the stretchable wiring and which includes bismuth and tin, and a second electrode layer on a side thereof facing the solder and which includes bismuth and tin. A concentration of the bismuth in the first electrode layer is lower than a concentration of the bismuth in the second electrode layer, and the concentration of the bismuth in the second electrode layer is constant along a thickness direction thereof.

The present disclosure provides a method for producing a wiring substrate. A seeded substrate including an insulation substrate, a conductive undercoat layer, and a conductive seed layer provided in a first region, in that order, is first prepared. An insulation layer covering the seed layer and the undercoat layer is then formed. Subsequently, the insulation layer is etched to expose a surface of the seed layer and form a remaining insulation layer covering the undercoat layer in the second region. Subsequently, a voltage is applied between an anode and the seed layer while a solid electrolyte membrane containing a metal ion-containing aqueous solution disposed between the seed layer and the anode and the membrane and the seed layer pressed into contact with each other, thereby a metal layer being formed on the surface of the seed layer. Thereafter, the remaining insulation layer is removed and the undercoat layer is etched.

An aspect of the present invention relates to a conductive resin composition containing an epoxy resin, a curing agent, and a conductive powder, in which a loss modulus of a dried product or semi-cured product of the conductive resin composition at 170° C. is 0.1 MPa or more and 15 MPa or less.

A method of applying viscous media on a substrate is disclosed. In the method, the substrate is provided, which is arranged for mounting of electronic components thereon. Further, flux is provided on a deposit of solder paste, which deposit is arranged at a predetermined position on the substrate. The flux is provided by a non-contact dispensing process, such as jetting. By providing flux on the deposit prior to reflow, the risk of quality related issues, such as e.g. graping, advantageously is reduced.

A method for applying an electrical conductor to an electrically insulating substrate, the method comprising providing a flexible membrane with a pattern of grooves formed on a first surface thereof, and loading the grooves with a composition comprising particles of a conductive material. The composition is, or may be made, electrically conductive. Once the membrane is loaded, the grooved first surface of the membrane is brought into contact with a front or/and back surface of the substrate. A pressure is then applied between the substrate and the membrane(s) so that the composition loaded into the grooves adheres to the substrate. The membrane(s) may remain on the electrically insulating substrate. The electrically conductive particles in the composition can then be sintered to form a pattern of electrical conductors on the substrate, the pattern corresponding to the pattern formed in the membrane(s).

An apparatus is disclosed for transferring a pattern of a composition containing particles of an electrically conductive material and a thermally activated adhesive from a surface of a flexible web to a surface of a substrate. The apparatus comprises: respective drive mechanisms for advancing the web and the substrate to a nip through which the web and the substrate pass at the same time and where a pressure roller acts to press the surfaces of the web and the substrate against one another, a heating station for heating at least one of the web and the substrate prior to, or during, passage through the nip, to a temperature at which the adhesive in the composition is activated, a cooling station for cooling the web after passage through the nip, and a separating device for peeling the web away from the substrate after passage through the cooling station, to leave the pattern of composition adhered to the surface of the substrate.