In an embodiment, a multilayer ceramic capacitor 10 has a first metal layer 14 having many holes 14a, and a second metal layer 15 having many holes 15a, with a clearance CL provided in between in the length direction, on the other height-direction side face of the capacitor body; the first metal layer 14 is partially covered by a third part 12c of a first external electrode 12, while the remainder is exposed; and the second metal layer 15 is partially covered by a third part 13c of a second external electrode 13, while the remainder is exposed. The multilayer ceramic capacitor can have excellent heat dissipation property.

An electrified vehicle according to an exemplary aspect of the present disclosure includes, among other things, an electric machine electrically coupled to a battery pack through an inverter. Further, the inverter includes a capacitor with an internal cooling channel. A method is also disclosed.

An electrified vehicle according to an exemplary aspect of the present disclosure includes, among other things, an electric machine electrically coupled to a battery pack through an inverter. Further, the inverter includes a capacitor with an internal cooling channel. A method is also disclosed.

The invention relates to an electronic component. The electronic component 2 has an electrical assembly 3 having two electrical connections 4, 5 that are each formed on opposing faces of the assembly. For each connection 4, 5, the component has at least one electrically conductive connection element 9, 10 having a mounting foot 14, 15 for connection to a circuit carrier 22. According to the invention, the connection element 8, 9 has at least two metal layers 10, 11, 12, 13 at least on one section, wherein the metal layers are each formed from different metals and integrally connected to one another. Preferably, one metal layer 12, 13 from the metal layers has greater thermal conductivity than the other metal layer 10, 11.

The invention relates to an electronic component. The electronic component 2 has an electrical assembly 3 having two electrical connections 4, 5 that are each formed on opposing faces of the assembly. For each connection 4, 5, the component has at least one electrically conductive connection element 9, 10 having a mounting foot 14, 15 for connection to a circuit carrier 22. According to the invention, the connection element 8, 9 has at least two metal layers 10, 11, 12, 13 at least on one section, wherein the metal layers are each formed from different metals and integrally connected to one another. Preferably, one metal layer 12, 13 from the metal layers has greater thermal conductivity than the other metal layer 10, 11.

An improved multilayered ceramic capacitor is provided wherein the capacitor has improved heat dissipation properties. The capacitor comprises first internal electrodes and second internal electrodes wherein the first internal electrodes are parallel with, and of opposite polarity, to the second internal electrodes. Dielectric layers are between the first internal electrodes and second internal electrodes and a thermal dissipation channel is in at least one dielectric layer. A thermal transfer medium is in the thermal dissipation channel.

An improved multilayered ceramic capacitor is provided wherein the capacitor has improved heat dissipation properties. The capacitor comprises first internal electrodes and second internal electrodes wherein the first internal electrodes are parallel with, and of opposite polarity, to the second internal electrodes. Dielectric layers are between the first internal electrodes and second internal electrodes and a thermal dissipation channel is in at least one dielectric layer. A thermal transfer medium is in the thermal dissipation channel.

A capacitor comprises an electrically conductive cylinder, an electrically conductive or semi-conductive cylindrical shell or shell segment arranged concentrically around the electrically conductive cylinder, and a dielectric arranged between the electrically conductive cylinder and the electrically conductive or semi-conductive cylindrical shell or shell segment. The dielectric comprises a particulate composite including a matrix material having a non-zero (e.g. negative) thermal coefficient of relative permittivity and a particulate filler material blended with the matrix material, the particulate filler material having an opposite (e.g. positive thermal) coefficient of relative permittivity. The positive thermal coefficient of relative permittivity is thereby selected such that the capacitance value of the capacitor is constant within a stability margin over a predefined temperature interval.

A capacitor comprises an electrically conductive cylinder, an electrically conductive or semi-conductive cylindrical shell or shell segment arranged concentrically around the electrically conductive cylinder, and a dielectric arranged between the electrically conductive cylinder and the electrically conductive or semi-conductive cylindrical shell or shell segment. The dielectric comprises a particulate composite including a matrix material having a non-zero (e.g. negative) thermal coefficient of relative permittivity and a particulate filler material blended with the matrix material, the particulate filler material having an opposite (e.g. positive thermal) coefficient of relative permittivity. The positive thermal coefficient of relative permittivity is thereby selected such that the capacitance value of the capacitor is constant within a stability margin over a predefined temperature interval.

A capacitor assembly includes a capacitor having ends. A terminal covers less than an area of one end. A wire bond has opposing ends with one end being coupled to the terminal and is configured to break connection with a circuit when an electrical current through the wire bond reaches a fusing current. An energy storage module includes at least two capacitor assemblies. The wire bond of one capacitor is electrically connected to the second terminal of an adjacent capacitor. An energy storage assembly includes two energy storage modules stacked one on top of the other. A pulse forming network includes conductors and at least two energy storage modules. A method of making a module includes charging each of the capacitors, removing each capacitor that fails, connecting one end of a wire bond to one terminal and connecting the other end to an adjacent capacitor or to a conductor.