Abstract: A method for manufacturing a circuit board on which an electronic component is mounted, includes at least the steps of (a) supplying a liquid photo-polymerizable adhesive containing conductive particles dispersed therein to a surface of a printed board, to form an adhesive layer on the board surface; (b) irradiating the photo-polymerizable adhesive with ultraviolet light to turn into a gel, to provide adhesiveness to the adhesive layer; and (c) pressing the electronic component against the component mounting portion of the printed board from an upper surface side of the adhesive layer, to form an electrical connection between the electronic component and the component mounting portion, and in the method, the photo-polymerizable adhesive is a delayed reactive adhesive.

Abstract: A conductive paste includes a filler component and a flux component; the filler component including a first conductive filler and a second conductive filler having different melting points, and the melting point of the first conductive filler being higher than the melting point of the second conductive filler by 20° C. or more; the flux component including a first flux and a second flux having different melting points, the melting point of the first flux being higher than the melting point of the second flux, and the melting point of the first flux being higher than the melting point of the second conductive filler by 15° C. to 45° C.; and the melting point of the second flux being equal to or less than the melting point of the second conductive filler.

Abstract: An electronic module 10 includes: a circuit board 12 having a first surface and a second surface opposite the first surface; and a plurality of electronic components 14 mounted thereon. The electronic components 14 are sealed at the first surface of the circuit board 12, with a mold body 16 composed of a resin composition. A shield layer 28 is formed on the surface of the mold body 16. The glass transition temperature of a resin included in the mold body 16 is higher than the glass transition temperatures of resins included in the circuit board 12 and the shield layer 28, respectively. The modulus of elasticity of the mold body at 25° C. is 10 to 18 GPa, and the thickness of the circuit board is 0.3 to 1.0 mm.

Abstract: Including a wiring board having an electronic component mounted at least on a first surface, a resin applied at least between the electronic component and the wiring board, and a through-hole provided in a region corresponding to the mounting position of the electronic component in the wiring board, a protrusion is formed on the wiring board so as to overlap at least with the electronic component, around a region corresponding to the mounting position of the electronic component.

Abstract: A mounting structure is provided that can suppress flux from spreading, secure a connecting strength between a circuit board and an electronic component with underfill, and achieve a stable electrical connection between lands and terminals. The mounting structure is configured with a flat electronic component and a circuit board, and a plurality of lands provided on the undersurface of the electronic component and a plurality of terminals provided on the mounting surface of the circuit board so as to correspond to the plurality of lands are bonded with solder. The circuit board includes a means for holding flux separated from the solder in the proximity of at least one of the plurality of terminals.

Abstract: A conductive bonding material having an improved preservation stability, and hardens when desired, preferably immediately hardens at a low temperature is provided. In one invention, the conductive bonding material comprises a conductive particle ingredient, an epoxy resin ingredient, and a hardening agent ingredient for said epoxy resin and the hardening agent ingredient for said epoxy resin further comprise a reforming agent having a thiol group. In another invention, a conductive bonding material comprising an epoxy resin hardening ingredient, wherein said epoxy resin hardening ingredient contains a sulfur-containing compound having an end group which can coordinate with a surface of the metallic particles, and the sulfur-containing compound comes to perform as a hardening agent for the epoxy resin by dissociating from the surface of the metallic particles. The conductive bonding material may contain fragrance.

Abstract: A structure with electronic component mounted therein includes a wiring board on which an electronic component is mounted at least on its first face, resin provided at least between the electronic component and the wiring board, and a plurality of holes formed in the wiring board at region corresponding to a mounting position of the electronic component. The holes are filled with the resin. This suppresses warpage of the structure with electronic component mounted therein, and also improves reliability by reducing a stress applied to a bonding section between the wiring board and the electronic component.

Abstract: Circuit board having conductor wiring and connection terminal; anisotropic conductive resin layer provided on one surface of circuit board; and plurality of electronic components respectively provided with electrode terminals in positions facing the connection terminal are included. The anisotropic conductive resin layer includes at least one kind of conductive particles selected from coiled conductive particles, fiber fluff conductive particles and conductive particles provided with a plurality of conductive protrusions, and resin binder; electrically couples electrode terminals of plurality of electronic components to connection terminals to each other with conductive particles; mechanically fixes electronic components and circuit board to each other; and protects conductor wiring.

Abstract: A semiconductor device mounted structure includes a semiconductor device having a plurality first electrodes, a circuit board having a plurality of second electrodes, a plurality of bumps respectively formed on the plurality of first electrodes, a plurality of bonding members respectively positioned between the bumps and the second electrodes to electrically connect the first electrodes to the second electrodes via the bumps, and a plurality of reinforcing resin members respectively positioned around the bonding members so as to cover at least the bonding members and bonding regions between the bonding members and the bumps. Adjacent reinforcing resin members are spaced away from each other so as not to have contact with each other without being in contact with the semiconductor device. This semiconductor device mounted structure enhances the reliability of joints in impact resistance and makes it easy to repair it.

Abstract: Disclosed is an electrically conductive paste which enables to reduce the level of void growth in a conducting pathway formed in a joint part produced after curing the electrically conductive paste in the implementation of an electronic component on a circuit board by using the electrically conductive paste, and which contains a reduced amount of a viscosity-adjusting/thixotropy-imparting additive. Two Sn-containing low-melting-point alloy particles having different melting points and different average particle diameters are selected as electrically conductive filler components to be used in an electrically conductive paste, and the two alloy particles are mixed at a predetermined ratio for use.

Abstract: A conductive bonding material having an improved preservation stability, and hardens when desired, preferably immediately hardens at a low temperature is provided. In one invention, the conductive bonding material comprises a conductive particle ingredient, an epoxy resin ingredient, and a hardening agent ingredient for said epoxy resin and the hardening agent ingredient for said epoxy resin further comprise a reforming agent having a thiol group. In another invention, a conductive bonding material comprising an epoxy resin hardening ingredient, wherein said epoxy resin hardening ingredient contains a sulfur-containing compound having an end group which can coordinate with a surface of the metallic particles, and the sulfur-containing compound comes to perform as a hardening agent for the epoxy resin by dissociating from the surface of the metallic particles. The conductive bonding material may contain fragrance.

Abstract: In order to easily inject underfill resin and perform molding with reliability, groove sections are formed on a surface of a circuit board such that the ends of the groove sections extend to semiconductor elements. Low-viscosity underfill resin applied dropwise is guided by the groove sections and flows between the circuit board and the semiconductor elements. The underfill resin hardly expands to regions outside the semiconductor elements.

Abstract: The present invention provides an electrically conductive adhesive which prevents migration and sulfuration of a metal component in electronic component mounting. The electrically conductive adhesive includes a thermosetting resin and metal filler particles dispersed in the thermosetting resin. It is possible to use, as the metal filler particles, metal filler particles having a composition including an alloy of Ag with at least one metal selected from the group consisting of Sn, Cu, In, Bi and Ni, a mixture of such metal filler particles and Ag filler particles, and metal filler particles including Ag filler particles and a coating layer formed on the surface of the Ag filler particles using a metal such as Sn.

Abstract: Disclosed is a solder material which enables to realize a lower mounting temperature when an electronic component is mounted. Also disclosed are a solder paste and a conductive adhesive. Specifically disclosed is a solder material having a basic composition composed of Sn, Bi and In. This solder material may further contain at least one metal selected from the group consisting of Cu, Ge and Ni. A solder paste which enables to realize a low-temperature mounting can be obtained by blending a flux component into the solder material. A conductive adhesive which enables to realize a low-temperature mounting can be obtained by blending a resin component into the solder material.

Abstract: A package structure includes a first printed wiring board having mounted on a top surface a plurality of electronic components including at least one first electronic component, a second printed wiring board stacked on the top surface side of the first printed wiring board, and a plurality of connecting members for mechanically connecting the first and second printed wiring boards while maintaining a constant gap therebetween, the connecting members including a first cured resin for bonding a top surface of the at least one first electronic component to a bottom surface of the second printed wiring board.

Abstract: The object of the invention is to provide a thermosetting resin composition which, in packaging an electronic circuit containing components incapable of withstanding elevated temperatures, employs low-melting solder particles, thereby enabling batch ref lowing and enabling packaging of components with excellent strength and toughness. The invention relates to a thermosetting resin composition which includes a metal filler component, a fluxing component and a thermosetting resin binder. The metal filler component includes at least one of bismuth (Bi) and indium (In), and tin (Sn). The fluxing component, which at least one of a compound of structural formula (1) below and a compound of structural formula (2) below, is used. In the above formulas, R1 to R6 are each a hydrogen or alkyl group, and X is an organic group which has a lone electron pair or double bond ? electrons and is capable of coordinating with a metal.

Abstract: A sealing material is provided which has sealing characteristics with low stress and high reliability upon mounting electronic parts on a board, and good repairablity after the sealing. The sealing material contains a heat-curable resin component and is characterized by ?E/?T in a range of from 0.5 MPa/° C. to 30 MPa/° C. wherein ?E/?T represents a ratio of change (?E) in storage elastic modulus (E) relative to a temperature change (?T) when the storage elastic modulus (E) is determined as the temperature is raised within a temperature range including a glass transition point (Tg) of the cured sealing material.

Abstract: A sealing material is provided, upon mounting semiconductor devices and/or electronic components which are relatively weak on a circuit board, which shows sealing characteristics that enables itself to seal the semiconductor devices and/or electronic components and connections therebetween with low stress and high reliability; and suitable repairability that enables merely semiconductor devices and/or electronic components which were determined to be off-specification after being sealed to be repaired with ease. The sealing material contains at least (a) a heat-curable resin component and (b) a hardener component therefor, and is characterized in that, once the sealing material is cured by being heated, the cured material has a glass transition temperature (Tg) in a temperature range of from ?80° C. to 50° C.

Abstract: The electronic component packaging structure having, as the moisture-proof coating layer, a polymer material that has sufficient moisture-proof performance and can be relatively easily peeled off from a circuit board and/or electronic components when repairing can be provided. The electronic component packaging structure of the invention comprises a circuit board, electronic components mounted on the circuit board and a moisture-proof coating layer covering the electronic components. The moisture-proof coating layer is constituted from a polymer material coating having at least two layers of a lower layer and an upper layer, and the polymer material forming the lower layer has higher swelling property and/or volubility to a repairing solvent that is selected from among hydrocarbon-based solvents than the polymer material forming the upper layer.

Abstract: A surface mount adhesive includes an epoxy resin, a curing agent, an accelerator, a first filler, and a second filler. The second filler has a specific gravity 1.1 to 3 times that of the first filler, and the second filler has a hardness higher than that of the first filler. The first filler has a largest particle size of 1 to 100 ?m, and the second filler has a largest particle size of 1 to 100 ?m, a specific gravity of 1.7 to 4.5, and a revised Mohs hardness of to 12. The weight ratio of the first filler to the second filler is from 1:3 to 3:1, and the surface mount adhesive has a specific gravity of 1.2 to 1.5. When the surface mount adhesive is dispensed, dispensing failures are suppressed, and dispensing stability is improved.