A multilayer ceramic capacitor includes an element body, a first terminal electrode, a second terminal electrode, and a plurality of internal electrodes. The plurality of internal electrodes include a plurality of first internal electrodes, a plurality of second internal electrodes, a plurality of third internal electrodes, and a plurality of fourth internal electrodes. The element body includes a plurality of first and second regions. The first regions are located between the first internal electrodes opposed with each other. The second regions are located between the first internal electrodes opposed to each other through the third internal electrodes, and between the second internal electrodes opposed to each other through the fourth internal electrodes. The first regions and the second regions are alternately located in the first direction.

A multilayer ceramic capacitor includes a body including a dielectric layer and first and second internal electrodes disposed with the dielectric layer interposed therebetween and disposed in point-symmetry with each other; first and second connection electrodes penetrating the body in a direction perpendicular to the dielectric layer and connected to the first internal electrode; third and fourth connection electrodes penetrating the body in a direction perpendicular to the dielectric layer and connected to the second internal electrode; first and second external electrodes disposed on both surfaces of the body and connected to the first and second connection electrodes; and third and fourth external electrodes spaced apart from the first and second external electrodes and connected to the third and fourth connection electrodes, and the first and second internal electrodes include a region in which an electrode is not disposed.

A metal-oxide-metal (MOM) capacitor is provided in the present invention. The MOM capacitor includes a capacitor element, wherein the capacitor element includes a first electrode and a second electrode. A projection of the first electrode includes a closed pattern in the vertical projection direction. A projection of the second electrode is surrounded by the closed pattern of the projection of the first electrode in the vertical projection direction.

A capacitor component includes a body including a plurality of dielectric layers having a layered structure, and first internal electrodes and second internal electrodes alternately disposed with respective dielectric layers of the plurality of dielectric layers interposed therebetween, a first external electrode formed on a first surface and a second surface of the body opposing each other, and connected to the first internal electrodes, and a second external electrode formed on at least one of a third surface and a fourth surface of the body connecting the first surface to the second surface and opposing each other, and connected to the second internal electrodes. The capacitor component is divided into a plurality of capacitor units each including a portion of the first internal electrodes and a portion of the second internal electrodes, and the plurality of capacitor units include a first capacitor unit and a second capacitor unit.

A laminated ceramic capacitor having internal electrodes configured such that Sn is dissolved in Ni, and, in a region of each of the internal electrodes at a depth of 2 nm from a surface thereof facing a ceramic dielectric layer, a CV value representing variation of a Sn/(Ni+Sn) ratio (ratio of number of atoms) is less than or equal to 32%. As a conductive paste for forming the internal electrodes, a conductive paste containing a Ni powder and a tin oxide powder which is represented by SnO or SnO.sub.2 and has a specific surface area of more than or equal to 10 m.sup.2/g as determined by a BET method is used, or a conductive paste containing a Ni—Sn alloy powder is used, or a conductive paste containing a Ni—Sn alloy powder and a tin oxide powder which is represented by SnO or SnO.sub.2 and has a specific surface area of more than or equal to 10 m.sup.2/g is used.

Some embodiments include an apparatus having horizontally-spaced bottom electrodes supported by a supporting structure. Leaker device material is directly against the bottom electrodes. Insulative material is over the bottom electrodes, and upper electrodes are over the insulative material. Plate material extends across the upper electrodes and couples the upper electrodes to one another. The plate material is directly against the leaker device material. The leaker device material electrically couples the bottom electrodes to the plate material, and may be configured to discharge at least a portion of excess charge from the bottom electrodes to the plate material. Some embodiments include methods of forming apparatuses which include capacitors having bottom electrodes and top electrodes, with the top electrodes being electrically coupled to one another through a conductive plate. Leaker devices are formed to electrically couple the bottom electrodes to the conductive plate.

Some embodiments include an apparatus having horizontally-spaced bottom electrodes supported by a supporting structure. Leaker device material is directly against the bottom electrodes. Insulative material is over the bottom electrodes, and upper electrodes are over the insulative material. Plate material extends across the upper electrodes and couples the upper electrodes to one another. The plate material is directly against the leaker device material. The leaker device material electrically couples the bottom electrodes to the plate material, and may be configured to discharge at least a portion of excess charge from the bottom electrodes to the plate material. Some embodiments include methods of forming apparatuses which include capacitors having bottom electrodes and top electrodes, with the top electrodes being electrically coupled to one another through a conductive plate. Leaker devices are formed to electrically couple the bottom electrodes to the conductive plate.

A device includes a first capacitive energy module and a second capacitive energy module. The first capacitive energy module comprises a first tray that is configured to house a first plurality of capacitive energy components, a first electrode, and a second electrode. The second capacitive energy module comprises a second tray that is configured to house a second plurality of capacitive energy components, a third electrode, and a fourth electrode. The first capacitive energy module is connected to the second capacitive energy module via a plug connector that makes a solid connection.

A combined electric appliance with a multi-capacitive screen insulation core has three groups of capacitive screens of main capacitor C1, low-voltage capacitor C2 and anti-interference capacitor C3 arranged in an insulation core of a high-voltage electric appliance such as a high-voltage bushing, a cable terminal head or the like simultaneously. A voltage display apparatus, an insulation monitor and a local discharge detector which meet accuracy requirements access a terminal of the low-voltage capacitor C2. Energy is extracted from the terminal to power the electric appliance. A grounding part for current flow is sleeved with a current transformer. The insulation core is sleeved with annular zinc oxide arrester valve plates. Head ends of the valve plates are connected with a terminal of the bushing or the cable head. Tail ends of the valve plates are connected with a flange of the bushing or the cable head.

A multilayer fringe capacitor includes first and second interdigitated capacitor electrodes, both parallel to and intersecting a first planar surface; third and fourth interdigitated capacitor electrodes, the first and second electrodes parallel to and separated by a non-zero distance from the third and fourth electrodes; a first set of coupling vias that electrically couples the first electrode to the third electrode; and a second set of coupling vias that electrically couples the second electrode to the fourth electrode.