In one general aspect, an apparatus can include a first module including a first semiconductor die, and a first heatsink coupled to the first module where the first heatsink includes a substrate and a first plurality of protrusions. The apparatus can also include a second module including a second semiconductor die, and a second heatsink coupled to the second module and including a second plurality of protrusions. The apparatus can also include a cover defining a channel where the first plurality of protrusions of the first heatsink and the second plurality of protrusions of the second heatsink are disposed within the channel.

Electronic equipment includes a plurality of heat generating elements, a single heat sink, and a single cover. The heat generating elements are arranged adjacent to one another in a one-dimensional array in a predetermined alignment direction. The faces of the heat generating elements on one side are fixed directly or indirectly to the heat sink. The faces of the heat generating elements on the other side are in direct or indirect contact with the cover. The cover is fixedly screwed to the heat sink at opposite ends in the alignment direction on the outer side of the heat generating elements. The heat generating elements are sandwiched and held between the heat sink and the cover. This allows heat generated by the heat generating elements to be efficiently radiated via the heat sink and allows the heat generating elements to be easily connected to the heat sink.

A cooling device for dissipating heat from articles to be cooled, such as power electronic modules, having at least one preferably rigid heat sink which consists in particular of solid material, preferably composed of metal, for example composed of aluminium, and which is intended to absorb heat from one or more articles to be cooled, and having a cooling fluid chamber for accommodating cooling fluid, in particular cooling liquid, to which the heat absorbed by the heat sink can be transferred. The cooling device has at least two preferably rigid heat sinks which consist in particular of solid material and which are connected to one another in an articulated manner, in particular by way of a heat sink joint, in such a way that the two heat sinks are movable relative to one another in different, in particular parallel planes.

An arrangement having a cooling device for dissipating heat from articles to be cooled which has at least one heat sink that has a heat absorption surface composed of metal and that is intended to absorb heat from one or more articles to be cooled, and also a cooling fluid chamber for accommodating cooling fluid to which the heat absorbed by the heat sink can be transferred, and having at least one article to be cooled which has a preferably planar heat emission surface composed of metal. To optimize the heat conduction between the heat sink and the article to be cooled, the heat absorption surface of the heat sink bears directly against the heat emission surface of the article to be cooled without an intermediate layer composed of air-displacing material, or, if necessary, with the use of an intermediate layer composed of air-displacing material that is thin.

One example heat sink includes a heat dissipation substrate, a connector, and a fastener. The heat dissipation substrate is configured to dissipate heat for a packaged chip located on a circuit board, and the heat dissipation substrate is located on a surface that is of the packaged chip and that is opposite to the circuit board. A first heat dissipation substrate and a second heat dissipation substrate of the heat dissipation substrate each have a heat conduction surface that conducts heat with a chip in the packaged chip. Different heat conduction surfaces correspond to different chips.

A problem to be solved by the present invention is to prevent smoke emission and ignition of a power semiconductor element that is installed inside a power conversion device connected to a battery in the field of power electronics, for example. A semiconductor holding device according to the present invention includes: a package which houses a power semiconductor element therein and dissipates heat to a cooler from a first surface of the package; a plate covering a second surface opposing the first surface of the package; and a pressing member pressing the plate against the package.

In one general aspect, an apparatus can include a module including a semiconductor die. The apparatus can include a heatsink coupled to the module and including a substrate, and a plurality of protrusions. The apparatus includes a cover defining a channel where the channel is outside of the module and the plurality of protrusions of the heatsink are disposed within the channel, and a sealing mechanism is disposed between the cover and the module is in contact with the module.

The present disclosure concerns a mounting device for semiconductor packages, and a heat dissipation assembly with such a mounting device. The mounting device includes a bottom side comprising one or more cavities to house semiconductor packages, and a top side comprising a plurality of holes extending from the bottom side to the top side for accommodating contact pins of the semiconductor packages. A fixation mechanism fixes the mounting device to a heat dissipation structure.

A semiconductor package has central region and peripheral region surrounding central region. The semiconductor package includes dies, encapsulant, and redistribution structure. The dies include functional die and first dummy dies. Functional die is disposed in central region. First dummy dies are disposed in peripheral region. Redistribution structure is disposed on encapsulant over the dies, and is electrically connected to functional die. Vacancy ratio of central region is in the range from 1.01 to 3.00. Vacancy ratio of the peripheral region is in the range from 1.01 to 3.00. Vacancy ratio of central region is a ratio of total area of central region to total area occupied by dies disposed in central region. Vacancy ratio of peripheral region is a ratio of total area of peripheral region to total area occupied by first dummy dies disposed in peripheral region.

An apparatus including first and second substrates. The first and second substrates each include a base and at least one peripheral wall extending from the base. One of the at least one peripheral walls of the first or second substrates includes at least one well, and the other of the at least one peripheral walls of the first or the seconds substrate that does not include a well is mechanically anchored to the well. The apparatus includes a stack having a first and second end, and the stack is disposed on the base of the first and/or the second substrates at the first and/or second ends. The stack includes at least one element configured to generate energy.