A composite assembly of three stacked joining partners, and a corresponding method. The three stacked joining partners are materially bonded to one another by an upper solder layer and a lower solder layer. An upper joining partner and a lower joining partner are fixed in their height and have a specified distance from one another. The upper solder layer is fashioned from a first solder agent, having a first melt temperature, between the upper joining partner and a middle joining partner. The second solder layer is fashioned from a second solder agent, having a higher, second melt temperature, between the middle joining partner and the lower joining partner. The upper joining partner has an upwardly open solder compensating opening filled with the first solder agent, from which, to fill the gap between the upper joining partner and the middle joining partner, the first solder agent subsequently flows into the gap.

A process for batch fabrication of circuit components is disclosed via simultaneously packaging multiple circuit component dice in a matrix. Each die has electrodes on its tops and bottom surfaces to be electrically connected to a corresponding electrical terminal of the circuit component it's packaged in. For each circuit component in the matrix, the process forms preparative electrical terminals on a copper substrate. Component dice are pick-and-placed onto the copper substrate with their bottom electrodes landing on corresponding preparative electrical terminal. Horizontal conductor plates are then placed horizontally on top of the circuit component dice, with bottom surface at one end of each plate landing on the dice's top electrode. An opening is formed at the opposite end and has vertical conductive surfaces. A vertical conductor block is placed into the opening and lands on the preparative electrical terminal, and the opening's vertical conductive surfaces facing the top end side surface of the vertical block. A thermal reflow then simultaneously melts pre-applied soldering material so that each circuit component die and its vertical conductor block are soldered to the copper substrate below and its horizontal conductor plate above.

A composite assembly of three stacked joining partners, and a corresponding method. The three stacked joining partners are materially bonded to one another by an upper solder layer and a lower solder layer. An upper joining partner and a lower joining partner are fixed in their height and have a specified distance from one another. The upper solder layer is fashioned from a first solder agent, having a first melt temperature, between the upper joining partner and a middle joining partner. The second solder layer is fashioned from a second solder agent, having a higher, second melt temperature, between the middle joining partner and the lower joining partner. The upper joining partner has an upwardly open solder compensating opening filled with the first solder agent, from which, to fill the gap between the upper joining partner and the middle joining partner, the first solder agent subsequently flows into the gap.

A semiconductor device includes: a seal portion; a first electronic element; a second lead terminal having one end that is disposed to be close to the one end of the first lead terminal within the seal portion, and another end that is exposed from another end of the seal portion, the other end of the seal portion being along the longitudinal direction; a first connecting element disposed within the seal portion, and having one end that is electrically connected to the first electrode disposed on the first electronic element, and another end that is electrically connected to the one end of the second lead terminal; and a conductive bonding agent.

A semiconductor device includes: a seal portion; a first electronic element; a second lead terminal having one end that is disposed to be close to the one end of the first lead terminal within the seal portion, and another end that is exposed from another end of the seal portion, the other end of the seal portion being along the longitudinal direction; a first connecting element disposed within the seal portion, and having one end that is electrically connected to the first electrode disposed on the first electronic element, and another end that is electrically connected to the one end of the second lead terminal; and a conductive bonding agent.

A process for batch fabrication of circuit component is disclosed via simultaneously packaging multiple circuit component dice in a matrix. Each die has electrodes on its tops and bottom surfaces to be electrically connected to a corresponding electrical terminal of the circuit component it's packaged in. For each circuit component in the matrix, the process forms preparative electrical terminals on a copper substrate. Component dice are pick-and-placed onto the copper substrate with their bottom electrodes landing on corresponding preparative electrical terminal. Horizontal conductor plates are then placed horizontally on top of the circuit component dice, with bottom surface at one end of each plate landing on the dice's top electrode. An opening is formed at the opposite end and has vertical conductive surfaces. A vertical conductor block is placed into the opening and lands on the preparative electrical terminal, and the opening's vertical conductive surfaces facing the top end side surface of the vertical block. A thermal reflow then simultaneously melts pre-applied soldering material so that each circuit component die and its vertical conductor block are soldered to the copper substrate below and its horizontal conductor plate above.

The semiconductor device includes a semiconductor element, and an electro-conductive first plate-like part electrically connected to a top-face-side electrode of the semiconductor element and including a first joint part projecting from a side face, and an electro-conductive second plate-like part including a second joint part projecting from a side face. A bottom face of the first joint part and a top face of the second joint part face one another, and are electrically connected via an electro-conductive bonding material. A bonding-material-thickness ensuring means is provided in a zone where the bottom face of the first joint part and the top face of the second joint part face one another to ensure a thickness of the electro-conductive bonding material between an upper portion of a front end of the second joint part and the bottom face of the first joint part.

An object of the invention is to provide: a manufacturing method for a highly reliable power semiconductor device which prevents breakage of an conductor pattern and an insulating layer, and has bonding strength higher than that by the conventional bonding between the electrode terminal and the conductor pattern; and that power semiconductor device. Breakage of the conductor pattern and the insulating layer is prevented due to inclusion of: a step of laying an electrode terminal on a protrusion provided on a conductor pattern placed on a circuit-face side of a ceramic board so that a center portion of a surface to be bonded of the electrode terminal makes contact with a head portion of the protrusion; a step of pressurizing and ultrasonically vibrating a surface opposite to the surface to be bonded, of the electrode terminal, using an ultrasonic horn, to thereby bond the electrode terminal to the conductor pattern.

An object of the invention is to provide: a manufacturing method for a highly reliable power semiconductor device which prevents breakage of an conductor pattern and an insulating layer, and has bonding strength higher than that by the conventional bonding between the electrode terminal and the conductor pattern; and that power semiconductor device. Breakage of the conductor pattern and the insulating layer is prevented due to inclusion of: a step of laying an electrode terminal on a protrusion provided on a conductor pattern placed on a circuit-face side of a ceramic board so that a center portion of a surface to be bonded of the electrode terminal makes contact with a head portion of the protrusion; a step of pressurizing and ultrasonically vibrating a surface opposite to the surface to be bonded, of the electrode terminal, using an ultrasonic horn, to thereby bond the electrode terminal to the conductor pattern.

An object of the invention is to provide: a manufacturing method for a highly reliable power semiconductor device which prevents breakage of an conductor pattern and an insulating layer, and has bonding strength higher than that by the conventional bonding between the electrode terminal and the conductor pattern; and that power semiconductor device. Breakage of the conductor pattern and the insulating layer is prevented due to inclusion of: a step of laying an electrode terminal on a protrusion provided on a conductor pattern placed on a circuit-face side of a ceramic board so that a center portion of a surface to be bonded of the electrode terminal makes contact with a head portion of the protrusion; a step of pressurizing and ultrasonically vibrating a surface opposite to the surface to be bonded, of the electrode terminal, using an ultrasonic horn, to thereby bond the electrode terminal to the conductor pattern.