A highly-reliable semiconductor device has improved adhesion between a sealing material and a sealed metal member and/or a case member. In some implementations, the semiconductor device includes: a laminated substrate on which a semiconductor element is mounted; and a sealing material. In some implementations, the sealing material contains an epoxy base resin, a curing agent, and a phosphonic acid.

A highly-reliable semiconductor device has improved adhesion between a sealing material and a sealed metal member and/or a case member. In some implementations, the semiconductor device includes: a laminated substrate on which a semiconductor element is mounted; and a sealing material. In some implementations, the sealing material contains an epoxy base resin, a curing agent, and a phosphonic acid.

Semiconductor chip package device and semiconductor chip package method are provided. The semiconductor chip package device includes: a lead frame, chips, an encapsulating layer, and an electroplating layer. The lead frame includes a first surface, a second surface, first grooves, second grooves, and third grooves. The first grooves are connected to the second grooves to form through holes and the third grooves disposed at ends of the lead frame. The chips are electrically connected to the lead frame. The encapsulating layer is formed by using an encapsulating material to encapsulate the chips and at least a portion of the lead frame. The first grooves are filled with the encapsulating material. The electroplating layer is disposed on the second surface of the lead frame, and extends into the third grooves or into the third grooves and the second grooves.

Semiconductor chip package device and semiconductor chip package method are provided. The semiconductor chip package device includes: a lead frame, chips, an encapsulating layer, and an electroplating layer. The lead frame includes a first surface, a second surface, first grooves, second grooves, and third grooves. The first grooves are connected to the second grooves to form through holes and the third grooves disposed at ends of the lead frame. The chips are electrically connected to the lead frame. The encapsulating layer is formed by using an encapsulating material to encapsulate the chips and at least a portion of the lead frame. The first grooves are filled with the encapsulating material. The electroplating layer is disposed on the second surface of the lead frame, and extends into the third grooves or into the third grooves and the second grooves.

Systems and methods for a semiconductor device having reinforced packaging are provided. The device generally includes a substrate and one or more integrated circuit dies electrically coupled to the substrate with wire bonds. The device includes an encapsulant enclosing the one or more dies and the wire bonds. The package can include a reinforcing layer positioned on one or more surfaces of the encapsulant, a reinforcing wire extending through the encapsulant, or entrained reinforcing fiber portions positioned throughout the encapsulant. The reinforcing layer can be textile woven from synthetic or natural fibers, such as aramid, carbon, or glass. The package can be formed by disposing a reinforcing textile layer in a mold, placing a die and substrate in the mold with a liquid encapsulant, and hardening the liquid encapsulant to adhere the reinforcing textile layer, the encapsulant, the die, and the substrate together.

Systems and methods for a semiconductor device having reinforced packaging are provided. The device generally includes a substrate and one or more integrated circuit dies electrically coupled to the substrate with wire bonds. The device includes an encapsulant enclosing the one or more dies and the wire bonds. The package can include a reinforcing layer positioned on one or more surfaces of the encapsulant, a reinforcing wire extending through the encapsulant, or entrained reinforcing fiber portions positioned throughout the encapsulant. The reinforcing layer can be textile woven from synthetic or natural fibers, such as aramid, carbon, or glass. The package can be formed by disposing a reinforcing textile layer in a mold, placing a die and substrate in the mold with a liquid encapsulant, and hardening the liquid encapsulant to adhere the reinforcing textile layer, the encapsulant, the die, and the substrate together.

A semiconductor module includes: a first metal plate including a first mount part joined with a bottom-surface electrode of a first switching element, a second mount part joined with a positive-electrode terminal, and a first narrow part between the first and second mount parts and being narrower than a part jointing the first switching element to the first mount part and the positive-electrode terminal; a second metal plate being joined with a bottom-surface electrode of a second switching element, and connected to a top-surface electrode of the first switching element; a third metal plate including a sixth mount part joined with a negative-electrode terminal, a seventh mount part connected to a top-surface electrode of the second switching element, and being narrower than the negative-electrode terminal, and a second narrow part between the sixth and seventh mount parts; and a snubber circuit connecting the first and second narrow parts.

A semiconductor module includes: a first metal plate including a first mount part joined with a bottom-surface electrode of a first switching element, a second mount part joined with a positive-electrode terminal, and a first narrow part between the first and second mount parts and being narrower than a part jointing the first switching element to the first mount part and the positive-electrode terminal; a second metal plate being joined with a bottom-surface electrode of a second switching element, and connected to a top-surface electrode of the first switching element; a third metal plate including a sixth mount part joined with a negative-electrode terminal, a seventh mount part connected to a top-surface electrode of the second switching element, and being narrower than the negative-electrode terminal, and a second narrow part between the sixth and seventh mount parts; and a snubber circuit connecting the first and second narrow parts.

Provided is a method for bonding an insulated coating wire, which is capable of stably bonding a metal wire in an insulated coating wire and an electrode. One aspect of the present invention provides a method for bonding an insulated coating wire for electrically connecting a first electrode 12 and a second electrode to each other by an insulated coating wire 11 in which a metal wire is coated with an organic substance, the method including: a step (a) for placing the insulated coating wire 11 onto the first electrode 12; a step (b) for exposing a metal wire from the insulated coating wire; and a step (c) for forming a first bump over the exposed metal wire and the first electrode to electrically connect the metal wire to the first electrode.

Provided is a method for bonding an insulated coating wire, which is capable of stably bonding a metal wire in an insulated coating wire and an electrode. One aspect of the present invention provides a method for bonding an insulated coating wire for electrically connecting a first electrode 12 and a second electrode to each other by an insulated coating wire 11 in which a metal wire is coated with an organic substance, the method including: a step (a) for placing the insulated coating wire 11 onto the first electrode 12; a step (b) for exposing a metal wire from the insulated coating wire; and a step (c) for forming a first bump over the exposed metal wire and the first electrode to electrically connect the metal wire to the first electrode.