In general aspect, a module can include a substrate having a semiconductor circuit implemented thereon, and a negative power supply terminal electrically coupled with the semiconductor circuit via the substrate. The negative power supply terminal includes a connection tab arranged in a first plane. The module also includes a first positive power supply terminal electrically and a second positive power supply terminal that are coupled with the semiconductor circuit via the substrate. The first positive power supply terminal being laterally disposed from the negative power supply terminal, and including a connection tab arranged in the first plane. The second positive power supply terminal is laterally disposed from the negative power supply terminal and arranged in the first plane, such that the negative power supply terminal is disposed between the first positive power supply terminal and the second positive power supply terminal.

A module arrangement for power semiconductor devices, includes two or more heat spreading layers with a first surface and a second surface being arranged opposite to the first surface. At least two or more power semiconductor devices are arranged on the first surface of the heat spreading layer and electrically connected thereto. An electrical isolation stack comprising an electrically insulating layer and electrically conductive layers is arranged in contact with the second surface of each heat spreading layer. The at least two or more power semiconductor devices, the heat spreading layers and a substantial part of each of the electrical isolation stacks are sealed from their surrounding environment by a molded enclosure. Accordingly, similar or better thermal characteristic of the module can be achieved instead of utilizing high cost electrically insulating layers, and double side cooling configurations can be easily implemented, without the use of a thick baseplate.

In the present invention, in order to reduce parasitic inductances of a gate line and a source line of a power module to reduce a current deviation (current balancing) which is a problem when the power module composed of a plurality of parallel chips is driven, in a power module including a plurality of power semiconductor chips connected to gate lines and source lines extending from gate pins and source pins in parallel by different distances, a current area of each of the gate lines and the source lines connected to chips other than a first chip closest to the gate pin and the source pin is formed larger than a current area of each of the gate line and the source line connected to the first chip.

A power semiconductor module arrangement includes: a housing; first and second electrical contacts within the housing; and a mounting arrangement including a frame or body and first and second terminal elements. The mounting arrangement is inserted in and coupled to the housing. First ends of the first and second terminal elements mechanically and electrically contact the first and second electrical contacts, respectively. A middle part of each terminal element extends through the frame or body. A second end of each terminal element extends outside the housing. The first terminal element is dielectrically insulated from the second terminal element by a portion of the frame or body. The first terminal element is injected into and inextricably coupled to the frame or body. The second terminal element is arranged within a hollow space inside the frame or body and is detachably coupled to the frame or body.

A semiconductor module includes first and second semiconductor chips including first and second main electrodes, respectively; first and second connection terminals electrically connected to the first and second main electrodes, respectively; and an insulating sheet. The first connection terminal includes a first conductor portion including a first peripheral edge and a first terminal portion extending from the first peripheral edge in plan view, and the second connection terminal includes a second conductor portion including a second peripheral edge. A part of the first conductor portion overlap a part of the second conductor portion in plan view. The insulating sheet includes an insulating portion layered between the first and second conductor portions, and a first protruding portion positioned between a tip portion of the first terminal portion and the second peripheral edge in plan view, the first protruding portion forming an angle relative to a surface of the first terminal portion.

Provided is a semiconductor package having a package housing in an engraved surface form and a method of manufacturing the same, wherein the semiconductor package includes: at least one substrate on which at least one semiconductor chip is installed; at least one terminal lead electrically connected to the substrates; electrical connectors for connecting the semiconductor chips to the substrates or the terminal leads; a package housing covering the semiconductor chips, the electrical connectors, and the at least one substrate; at least one stopper which is formed of a material same as that of the package housing, is higher by a certain height than exposed surfaces of the substrates, is disposed on the exposed surfaces of the substrates, or covers at least a part of the exposed surfaces; and at least one heat sink transmitting heat from the semiconductor chips and radiating heat, wherein the at least a part of the exposed surfaces of the at least one substrate is formed on the upper surface, the lower surface, or the upper and lower surfaces of the package housing and the exposed surfaces of the at least one substrate are joined to the heat sinks by using heat transfer connectors interposed therebetween. Accordingly, the full thickness of the heat transfer connectors may be uniformly maintained.

A power module (10) and a manufacturing method thereof are disclosed. The power module (10) includes a power assembly (11) and a drive board (12). The power assembly (11) includes a substrate (111), a power chip (112), and a package body (113). The power chip (112) is disposed on a mounting surface (1110) of the substrate (111). The package body (113) packages the power chip (112) on the substrate (111). The drive board (12) is disposed in the package body (113) and is located on a side, of the power chip (112), that backs the mounting surface (1110). The drive board (12) is electrically connected to the power chip (112). In the power module, a parasitic parameter between the drive board (12) and the power assembly (11) can be reduced, thereby improving electrical performance of the power module (10).

A low parasitic inductance power module featuring staggered interleaving conductive members, including: at least one base extending in a length direction; a substrate on which at least one input bus bar and at least one output bus bar are provided; a first unit including a first circuit base portion disposed on the base in a width direction, a plurality of first power devices being disposed on the first circuit base portion, each first power device having a first current input end and a first current output end which are parallel connected, the first current input end or the first current output end being conducted to the first circuit base portion; and a second unit. The units are serially-connected to the bus bars via input conductive members and output conductive members arrayed in a staggered interleaving mode, whereby to create individual inductances counteracting with each other, reducing overall parasitic inductance.

A semiconductor device, having a substrate including an insulating plate and a circuit board provided on a front surface of the insulating plate. The circuit board has a first disposition area and a second disposition area with a gap therebetween, and a groove portion, of which a longitudinal direction is parallel to the gap, formed in the gap. The semiconductor device further includes a first semiconductor chip and a second semiconductor chip located on the circuit board in the first disposition area and the second disposition area, respectively, and a blocking member located in the gap across the groove portion in parallel to the longitudinal direction in a plan view of the semiconductor device.

Disclosed is a semiconductor module comprising a module substrate having a top surface and a bottom surface that are opposite to each other, a plurality of semiconductor packages on the top surface of the module substrate and arranged in a first direction parallel to the top surface of the module substrate, and a clip structure on the top surface of the module substrate and spaced apart from the plurality of semiconductor packages in the first direction. The clip structure includes a body part on the top surface of the module substrate and spaced apart from the plurality of semiconductor packages in the first direction, and a connection part that extends from the body part across a lateral surface of the module substrate onto the bottom surface of the module substrate.