In a multilayer ceramic capacitor, an interposer includes, on a side of a first external electrode in a length direction, a first through hole that penetrates the interposer in a stacking direction, and provides electrical conduction between a first joining electrode and a first mounting electrode. The first through hole further includes a first metal film provided on an inner wall thereof. The interposer includes, on a side of a second external electrode in the length direction, a second through hole that penetrates the interposer in the stacking direction, and provides electrical conduction between a second joining electrode and a second mounting electrode. The second through hole further includes a second metal film provided on an inner wall thereof. A first uncovered portion is provided, which is not covered by the first metal film, on a first surface of the inner wall of the first through hole, and a second uncovered portion is provided which is not covered by a second metal film on the first surface of the inner wall of the second through hole.

A method for printed circuit board design rework utilizing two components in series, the method includes selecting a first chip component and a second chip component for placement on an original land location previously occupied by an original chip component. The method further includes placing the first chip component and the second chip component on a chip component support structure. The method further includes soldering a first end of the first chip component to a first end of the second chip component. Responsive to transferring the first chip component and the second chip component to the original land location, the method further includes soldering a second end of the first chip component to a first land of the original land location. The method further includes soldering a second end of the second chip component to a second land of the original land location.

An electronic component includes: a multilayer capacitor including a capacitor body and first and second external electrodes respectively disposed on opposing end surfaces of the capacitor body; and an ESD member disposed on a first side surface of the multilayer capacitor perpendicular to a mounting surface of the multilayer capacitor, such that the ESD of the multilayer capacitor may be effectively controlled.

This application discloses a printed circuit board, a battery module, a battery pack, and an electrical device. The printed circuit board may include: a substrate, a pad, a solder paste layer, a component body, and a support assembly. The pad may be disposed above the substrate. The solder paste layer may be disposed above the pad. The component body may be disposed above the solder paste layer. The support assembly may be disposed between the pad and the component body to form a degassing space between the component body and the solder paste layer.

A multilayer capacitor include dielectric layers stacked in a direction perpendicular to a mounting surface of a capacitor body, and internal electrodes and an equivalent series inductance (ESL) control pattern formed on upper and lower portions of the dielectric layers, respectively. The internal electrodes have an area larger than that of the ESL control pattern, and the ESL control pattern is exposed to a mounting surface of a capacitor body.

An electronic component assembly is described which comprises a stack of electronic components wherein each electronic component comprises a face and external terminations. A component stability structure is attached to at least one face. A circuit board is provided wherein the circuit board comprises circuit traces arranged for electrical engagement with the external terminations. The component stability structure mechanically engages with the circuit board and inhibits the electronic device from moving relative to the circuit board.

A multilayer ceramic electronic component includes: a ceramic body including: an active part with dielectric layers interposed with a plurality of first and second internal electrodes; an upper cover part above the active part; a lower cover part below the active part and having a thickness greater than that of the upper cover part; and first and second external electrodes electrically connected to the first and second internal electrodes, respectively, wherein the first and second external electrodes are disposed on respective end surfaces of the ceramic body in a length direction and on a lower surface of the ceramic body in a thickness direction and are not disposed on an upper surface of the ceramic body in the thickness direction.

A capacitor component includes a body including a plurality of dielectric layers having a stacked structure and a plurality of first internal electrodes and a plurality of second internal electrodes alternately disposed with dielectric layers disposed therebetween. A first external electrode is on a first surface and a second surface of the body, on the opposing side of the body, and connected to the plurality of first internal electrodes. A second external electrode is on a third surface and a fourth surface of the body, opposing each other, and connected to one or more of the plurality of second internal electrodes.

A composite electronic component includes a composite body having a multilayer ceramic capacitor and a tantalum capacitor coupled to each other, so as to have an excellent acoustic noise reduction effect, a low equivalent series resistance (ESR)/equivalent series inductance (ESL), improved direct current (DC)-bias characteristics, and a low chip thickness.

A multilayer ceramic capacitor connected to an output electrode and an input electrode of a mounting substrate includes a laminated body. In the laminating direction of the laminated body, the shortest distance from an outer first internal electrode to the surface of an external electrode on the side closer to a first principal surface, and the shortest distance from an outer second internal electrode to the surface of an external electrode on the side closer to a second principal surface are each about 40 μm or less. In the width direction of the laminated body, the shortest distance from an end of an internal electrode to the surface of the external electrode on the side closer to a first side surface, and the shortest distance from an end of an internal electrode to the surface of the external electrode on the side closer to a second side surface are each about 40 μm or less.