An electrical connection terminal and an electrical connection assembly are disclosed. The electrical connection terminal has a base, and a plurality of tabs connected to the base. The plurality of tabs are separated from each other, and each of the plurality of tabs is adapted to mate with a mating terminal in a plug-in manner. In the present invention, the electrical connection terminal adopts a plurality of parallel tabs, so the length of the electrical connection terminal and the current flow path through the electrical connection terminal are reduced. Therefore, the electrical connection terminal of the present invention has low body resistance, less heating and is more suitable for high current applications.

An anisotropic conductive sheet has an insulation layer having a plurality of through-holes and a plurality of conductive layers each arranged on an inner wall surface of each of the plurality of through-holes. Each of the conductive layers has a base layer arranged on the inner wall surface of each of the through-holes and a metal plating layer arranged so as to contact with metal nanoparticles or a metal thin film in the base layer or the metal thin film. The base layer includes metal nanoparticles or a metal thin film and a binder, wherein at least a portion of the binder is arranged between the inner wall of each of the through-holes and the metal nanoparticles or the metal thin film. The binder is a sulfur-containing compound having a thiol group, a sulfide group or a disulfide group.

A bus bar includes a first joint that is joined to an output terminal of a first battery, a second joint that is joined to an output terminal of a second battery, a heat absorber that is disposed between the first joint and the second joint and has a heat capacity larger than heat capacities of the first joint and the second joint, and a displacement absorber that is disposed between the first joint and the second joint and deforms in response to a relative displacement of the first battery and the second battery.

A connected structure including: a first circuit member having a first electrode; a second circuit member having a second electrode; and a connecting portion provided between the first circuit member and the second circuit member and electrically connecting the first electrode and the second electrode to each other, wherein at least one of the first electrode and the second electrode has a layer made of Cu or Ag as an outermost surface thereof, and the connecting portion contains a conductive particle having a layer made of Pd or Au as an outermost surface thereof.

A connected structure including: a first circuit member having a first electrode; a second circuit member having a second electrode; and a connecting portion provided between the first circuit member and the second circuit member and electrically connecting the first electrode and the second electrode to each other, wherein at least one of the first electrode and the second electrode has a layer made of Cu or Ag as an outermost surface thereof, and the connecting portion contains a conductive particle having a layer made of Pd or Au as an outermost surface thereof.

A conductive film includes an elongated release film and a plurality of conductive adhesive film pieces provided on the release film. Then, the plurality of adhesive film pieces are arranged in a longitudinal direction X of the release film. For this reason, the adhesive film piece can be set to an arbitrary shape. Accordingly, it is possible to attach the adhesive film piece to adhesive surfaces having various shapes and to efficiently use the adhesive film piece.

A conductive film includes an elongated release film and a plurality of conductive adhesive film pieces provided on the release film. Then, the plurality of adhesive film pieces are arranged in a longitudinal direction X of the release film. For this reason, the adhesive film piece can be set to an arbitrary shape. Accordingly, it is possible to attach the adhesive film piece to adhesive surfaces having various shapes and to efficiently use the adhesive film piece.

This anisotropic conductive sheet includes: an insulating layer having a first surface and a second surface; and a plurality of conductive paths which are disposed so as to extend in the thickness direction inside the insulating layer and which are respectively exposed to the outside of the first surface and the second surface. The circumferential surface of the conductive paths includes a region where the surface area ratio represented by equation (1) is at least 1.04. Equation (1): surface area ratio = surface area / area

An anisotropic conductive film which suppresses occurrence of short circuit at the time of anisotropic conductive connection, prevents reduction in capturing capability of electrically conductive particles, enables favorable pushing of electrically conductive particles and exhibits not only favorable initial conductivity but also favorable conduction reliability, contains a first electrically conductive particle group and a second electrically conductive particle group, each including a plurality of electrically conductive particles, in an insulating binder. The first electrically conductive particle group and the second electrically conductive particle group are present in a first region and a second region, respectively, which differ from each other in the thickness direction of the anisotropic conductive film and are parallel to the plane direction. Moreover, the first electrically conductive particle group and the second electrically conductive particle group differ from each other in an existence state of the electrically conductive particles.

An anisotropic electrically conductive film that is suitable for use in fine-pitch FOG connections and COG connections and that also can reduce increases in production costs associated with increasing the electrically conductive particle density. The anisotropic electrically conductive film includes an electrically insulating adhesive layer and electrically conductive particles disposed within the electrically insulating adhesive layer. The anisotropic electrically conductive film has electrically conductive particle disposition regions that are disposed in a manner corresponding to the arrangement of terminals of electronic components to be connected. The electrically conductive particle disposition regions are formed periodically in the longitudinal direction of the anisotropic electrically conductive film. The anisotropic electrically conductive film also has buffer regions in which no electrically conductive particles are disposed that are formed between adjacent electrically conductive particle disposition regions for connection.