Provided is a power storage element including: an outer collector including outer opposing walls facing each other with a gap therebetween in an opposition direction, an inner collector including inner opposing walls, and an electrode member disposed in a space defined between the opposing walls. The electrode member includes: an electrode laminate having a sheet-like shape and including a positive electrode body, a negative electrode body, and a separator interposed between the positive and negative electrode bodies. The electrode laminate forms a plurality of unit electrode layers laminated in a lamination direction perpendicular to the opposition direction, and adjacent unit electrode layers in the lamination direction are continued in a bending manner at end portions of the unit electrode layers in an extension direction. The positive electrode body and the negative electrode body are in contact with a first collector and a second collector, respectively, to be electrically connected thereto.

A flexible cable includes an elongated flexible substrate including first and second surfaces on opposite sides thereof, a first capacitor electrode provided on the first surface side of the flexible substrate, the first capacitor electrode extending from a first end of the flexible substrate toward a second end of the flexible substrate, a second capacitor electrode provided on the second surface side of the flexible substrate, the second capacitor electrode extending from the second end of the flexible substrate toward the first end of the flexible substrate, a first connection portion provided at an end of the first capacitor electrode located at the first end of the flexible substrate, and a second connection portion provided at an end of the second capacitor electrode located at the second end of the flexible substrate.

A flexible cable includes an elongated flexible substrate including first and second surfaces on opposite sides thereof, a first capacitor electrode provided on the first surface side of the flexible substrate, the first capacitor electrode extending from a first end of the flexible substrate toward a second end of the flexible substrate, a second capacitor electrode provided on the second surface side of the flexible substrate, the second capacitor electrode extending from the second end of the flexible substrate toward the first end of the flexible substrate, a first connection portion provided at an end of the first capacitor electrode located at the first end of the flexible substrate, and a second connection portion provided at an end of the second capacitor electrode located at the second end of the flexible substrate.

A folding type capacitor includes a metal substrate wherein a through hole penetrates an inside thereof; at least one dielectric layer formed on a surface of the metal substrate and an inner peripheral surface of the through hole; and an electrode layer formed on the at least one dielectric layer, wherein the metal substrate has bending portions whose surfaces are facing each other. Thus, manufacturing process is more simplified since Al.sub.2O.sub.3 insulation layers are formed by anodizing the aluminum layer without forming the extra dielectric layers after forming the aluminum layer, so that the manufacturing cost can be reduced, and also a multi-stacked capacitor having a high capacitance and a high reliability can be provided by stacking capacitors including a plurality of aluminum oxide layers using a more simplified process.

A folding type capacitor includes a metal substrate wherein a through hole penetrates an inside thereof; at least one dielectric layer formed on a surface of the metal substrate and an inner peripheral surface of the through hole; and an electrode layer formed on the at least one dielectric layer, wherein the metal substrate has bending portions whose surfaces are facing each other. Thus, manufacturing process is more simplified since Al.sub.2O.sub.3 insulation layers are formed by anodizing the aluminum layer without forming the extra dielectric layers after forming the aluminum layer, so that the manufacturing cost can be reduced, and also a multi-stacked capacitor having a high capacitance and a high reliability can be provided by stacking capacitors including a plurality of aluminum oxide layers using a more simplified process.

A capacitive cable comprised six long, thin and narrow electrode plates or strips (101, 102, 103, 104, 105, 106). Typically, they are 5 km long, 10 cm wide and 0.5 mm thick of aluminum or copper foil. Individual ones of them are separated by 0.25 mm thick polypropylene ribbons (107) insulating the individual strips from each other in an insulating manner. The assembly of strips and ribbons is contained within an insulating sheath 108. At opposite ends (111,112), the alternate strips are cut off short and the remaining fingers (114,115) are joined together and to connection wires (116,117), typically by riveting (118). The wires are insulated and the insulating sheath extends onto the insulation of the wires, whereby the entire cable is insulated for safe contact with foreign objects between the ends.

A capacitive cable comprised six long, thin and narrow electrode plates or strips (101, 102, 103, 104, 105, 106). Typically, they are 5 km long, 10 cm wide and 0.5 mm thick of aluminum or copper foil. Individual ones of them are separated by 0.25 mm thick polypropylene ribbons (107) insulating the individual strips from each other in an insulating manner. The assembly of strips and ribbons is contained within an insulating sheath 108. At opposite ends (111,112), the alternate strips are cut off short and the remaining fingers (114,115) are joined together and to connection wires (116,117), typically by riveting (118). The wires are insulated and the insulating sheath extends onto the insulation of the wires, whereby the entire cable is insulated for safe contact with foreign objects between the ends.

A multi-layer ceramic electronic component includes: a ceramic body including a main surface, an end surface, and a side surface respectively perpendicular to a first axis, a second axis, and a third axis orthogonal to one another, a top portion that connects the main surface, the end surface, and the side surface to one another, and a plurality of internal electrodes laminated in a direction of the first axis; and an end external electrode including a corner portion located on the top portion, a base portion that covers the end surface and extends from the end surface to the main surface and the side surface, and a protrusion that protrudes from the base portion in a thickness direction, the protrusion including an L-shaped main surface protrusion located on the main surface and extending in directions of the second axis and the third axis from the corner portion.

A capacitive cable comprised six long, thin and narrow electrode plates or strips (101, 102, 103, 104, 105, 106). Typically, they are 5 km long, 10 cm wide and 0.5 mm thick of aluminum or copper foil. Individual ones of them are separated by 0.25 mm thick polypropylene ribbons (107) insulating the individual strips from each other in an insulating manner. The assembly of strips and ribbons is contained within an insulating sheath 108. At opposite ends (111,112), the alternate strips are cut off short and the remaining fingers (114,115) are joined together and to connection wires (116,117), typically by riveting (118). The wires are insulated and the insulating sheath extends onto the insulation of the wires, whereby the entire cable is insulated for safe contact with foreign objects between the ends.

A capacitive cable comprised six long, thin and narrow electrode plates or strips (101, 102, 103, 104, 105, 106). Typically, they are 5 km long, 10 cm wide and 0.5 mm thick of aluminum or copper foil. Individual ones of them are separated by 0.25 mm thick polypropylene ribbons (107) insulating the individual strips from each other in an insulating manner. The assembly of strips and ribbons is contained within an insulating sheath 108. At opposite ends (111,112), the alternate strips are cut off short and the remaining fingers (114,115) are joined together and to connection wires (116,117), typically by riveting (118). The wires are insulated and the insulating sheath extends onto the insulation of the wires, whereby the entire cable is insulated for safe contact with foreign objects between the ends.