A semiconductor module includes a rectangular base plate; a substrate which is placed on the base plate and on which a circuit including a semiconductor chip and so forth is formed; a rectangular parallelepiped case made of resin that is attached to the base plate and houses the substrate within; and a plurality of external terminals lower ends of which are fixed to the substrate with upper ends thereof being exposed on a top face of the case. The case is provided with a first case opening portion and a second case opening portion that are respectively formed by cutting off a front face and a rear face of the case from an upper edge thereof along a longitudinal direction thereof; and the top face of the case between the first case opening portion and the second case opening portion includes an external terminal holding portion to hold the plurality of external terminals along the longitudinal direction with the upper ends thereof being exposed. A sealing material is injected from the first case opening portion and the second case opening portion onto a top face of the substrate, and thereby the semiconductor module is sealed.

A semiconductor module includes a rectangular base plate; a substrate which is placed on the base plate and on which a circuit including a semiconductor chip and so forth is formed; a rectangular parallelepiped case made of resin that is attached to the base plate and houses the substrate within; and a plurality of external terminals lower ends of which are fixed to the substrate with upper ends thereof being exposed on a top face of the case. The case is provided with a first case opening portion and a second case opening portion that are respectively formed by cutting off a front face and a rear face of the case from an upper edge thereof along a longitudinal direction thereof; and the top face of the case between the first case opening portion and the second case opening portion includes an external terminal holding portion to hold the plurality of external terminals along the longitudinal direction with the upper ends thereof being exposed. A sealing material is injected from the first case opening portion and the second case opening portion onto a top face of the substrate, and thereby the semiconductor module is sealed.

A power electronics module is provided having one or more power converter semiconductor components. The power electronics module further has a substrate having a first surface to which the one or more components are mounted, and having an opposing second surface from which project a plurality of heat transfer formations for enhancing heat transfer from the substrate. The power electronics module further has a coolant housing which sealingly connects to the substrate to form a void over the heat transfer formations of the second surface. The coolant housing has an inlet for directing a flow of an electrically insulating coolant into the void and an outlet for removing the coolant flow from the void, whereby heat generated during operation of the one or more components is transferred into the coolant flow via the substrate.

A power electronics module is provided having one or more power converter semiconductor components. The power electronics module further has a substrate having a first surface to which the one or more components are mounted, and having an opposing second surface from which project a plurality of heat transfer formations for enhancing heat transfer from the substrate. The power electronics module further has a coolant housing which sealingly connects to the substrate to form a void over the heat transfer formations of the second surface. The coolant housing has an inlet for directing a flow of an electrically insulating coolant into the void and an outlet for removing the coolant flow from the void, whereby heat generated during operation of the one or more components is transferred into the coolant flow via the substrate.

A lens cap for a transistor outline (TO) package is provided that has an inner diameter of less than 4 mm. The lens cap includes a metal shell with a wall thickness of less than 0.2 mm and a thinned area surrounding the lens so that in the thinned area the wall thickness is reduced by at least 35%.

A lens cap for a transistor outline (TO) package is provided that has an inner diameter of less than 4 mm. The lens cap includes a metal shell with a wall thickness of less than 0.2 mm and a thinned area surrounding the lens so that in the thinned area the wall thickness is reduced by at least 35%.

A chip packaging method and package structure, the package structure including a substrate, a sensing chip coupled to the substrate, a plastic package layer located on the substrate, and a covering layer located on the plastic package layer and a first surface of the sensing chip; the sensing chip including the first surface and a second surface opposite to the first surface, and further including a sensing area located on the first surface; the second surface of the sensing chip faces towards the substrate; and the plastic package layer encloses the sensing chip, and the surface of the plastic package layer is flush with the first surface of the sensing chip.

A chip packaging method and package structure, the package structure including a substrate, a sensing chip coupled to the substrate, a plastic package layer located on the substrate, and a covering layer located on the plastic package layer and a first surface of the sensing chip; the sensing chip including the first surface and a second surface opposite to the first surface, and further including a sensing area located on the first surface; the second surface of the sensing chip faces towards the substrate; and the plastic package layer encloses the sensing chip, and the surface of the plastic package layer is flush with the first surface of the sensing chip.

The present invention makes it possible to inhibit decrease in optical performance due to a foreign object, while securing a space necessary for wire bonding. A cover (3) is configured such that a distance (z2) between an optical device (1) and a sub-cover member (32) becomes greater than a distance (z1) between the optical device (1) and a cover glass (31).

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.