The present invention provides a multilayer transformer PCB structure for an electric car and manufacturing method for the same, which includes first and second connecting copper tabs horizontally formed in plural on both surfaces of a base substrate, thereby forming inner layer circuits coupled to battery cells, and third and fourth connecting copper tabs stacked on a top surface of the first connecting copper tab and a top surface of the second connecting copper tab by patterning process a copper material several times as a predetermined thickness, thereby forming outer layer circuits coupled to the battery cells. According to the present invention configured thus, the transformer PCB for an electric car has a structure in which a conductive material having a predetermined thickness is stacked in a multilayer form, and thus an increased quantity of charges to be treated is highly distributed, thereby maximizing current efficiency.

A coil electrode 4 provided in a coil component 1a includes a plurality of inner metal pins 5a arranged on an inner peripheral side of a coil core 3, a plurality of outer metal pins 5b arranged on an outer peripheral side of the coil core 3 to form a plurality of pairs with the inner metal pins 5a, a plurality of lower wiring patterns 7 that connect lower ends of the inner metal pins 5a and the outer metal pins 5b in the pairs, and a plurality of upper wiring patterns 6 that connect upper ends of the outer metal pins 5b to upper ends of inner metal pins 5a adjacent to the inner metal pins 5a that form the pairs with the outer metal pins 5b.

A multilayer electronic component includes an element body including a plurality of base layers stacked in a first direction, an inner conductor disposed in the element body, and a mounting terminal connected to the inner conductor. The multilayer electronic component has a mount surface positioned on a mounted side when the multilayer electronic component is mounted. The mount surface is disposed so as not to intersect an axis along the first direction. The mounting terminal is disposed on the mount surface and embedded from the mount surface into the element body.

An inductor has a substrate and at least one coil of carbon nanotubes. A trench is formed in the substrate, and the carbon nanotubes are grown in the trench in order to form a coil for the inductor. In some embodiments, multiple coils may be formed in the trench as may be desired.

A method of manufacturing an inductor includes forming a step portion having a high-resolution pattern by using a photosensitive layer with photosensitive characteristics, and forming a low-resistance coil pattern by filling the step portion with a metal paste having a lower resistance than a photosensitive metal paste.

A coil electrode 4 provided in a coil component 1a includes a plurality of inner metal pins 5a arranged on an inner peripheral side of a coil core 3, a plurality of outer metal pins 5b arranged on an outer peripheral side of the coil core 3 to form a plurality of pairs with the inner metal pins 5a, a plurality of lower wiring patterns 7 that connect lower ends of the inner metal pins 5a and the outer metal pins 5b in the pairs, and a plurality of upper wiring patterns 6 that connect upper ends of the outer metal pins 5b to upper ends of inner metal pins 5a adjacent to the inner metal pins 5a that form the pairs with the outer metal pins 5b.

A coil electrode of a coil component includes a plurality of lower wiring patterns arranged on a lower surface of an insulating layer; a plurality of upper wiring patterns arranged on an upper surface of the insulating layer; a plurality of inner conductors disposed at an inner peripheral side of the coil core, each inner conductor connecting one end of the corresponding one of the lower wiring patterns and one end of a corresponding one of the upper wiring patterns forming the pair with the lower wiring pattern; and a plurality of outer conductors disposed at an outer peripheral side of the coil core, each outer conductor connecting the other end of the corresponding one of the lower wiring patterns and the other end of the corresponding one of the upper wiring patterns adjacent to an upper wiring pattern forming the pair with the lower wiring pattern.

In the multi-layer coil component, the lead conductor is exposed from the end surface of the element body and is connected to the external electrode provided on the end surface. When the lead conductor is led out to the end surface of the element body, the lead area can be easily increased as compared with the case where the lead conductor is led out to the side surface of the element body. Therefore, by connecting the coil and the external electrode via the lead conductor, high connectivity between the coil and the external electrode is achieved.

A coil component includes a main body made of a magnetic material, a linear inductor wiring conductor arranged in the main body, an electrically insulating pedestal having a top surface extending along the inductor wiring conductor in the main body and a pair of side surfaces each extending from both outer edges of the top surface in a direction intersecting the top surface, and a conductive seed layer provided over an entire region of at least a region sandwiched between the top surface of the pedestal and the inductor wiring conductor. When a width dimension of a surface of the inductor wiring conductor in contact with the seed layer is defined as a first width dimension and a width dimension of the seed layer is defined as a second width dimension, the second width dimension is larger than the first width dimension.

A photosensitive resin composition containing: a component (A) which is a high molecular weight compound having a photopolymerizable functional group and a carbon-nitrogen bond; a component (B) which is a low molecular weight compound having a photopolymerizable functional group; a component (C) which is a photopolymerization initiator; and a component (D) which is a triazole-based compound.