Abstract: A secondary heat exchanger includes a case and a first heat transfer tube portion. The case includes a box body and a first closing member. The box body is provided with a second opening on one side in a third direction. A first assembly in which the first heat transfer tube portion and the first closing member are assembled integrally is mounted to the box body so that a plurality of first heat transfer tubes are is inserted into the box body from the second opening and so that the second opening is closed by the first closing member.

Abstract: A manufacturing method for an electronic component includes: a step of forming an insulating layer on an outer electrode body so as to cover the outer electrode body, the outer electrode body being formed on a chip element which forms the electronic component; and a step of removing the insulating layer in a predetermined region of the outer electrode body by applying laser light to the insulating layer in the predetermined region so as to expose the predetermined region. The insulating layer has a higher absorption coefficient for the laser light than a material forming a surface of the outer electrode body.

Abstract: A secondary heat exchanger includes a case and a first heat transfer tube portion. The case includes a box body and a first closing member. The box body is provided with a second opening on one side in a third direction. A first assembly in which the first heat transfer tube portion and the first closing member are assembled integrally is mounted to the box body so that a plurality of first heat transfer tubes are is inserted into the box body from the second opening and so that the second opening is closed by the first closing member.

Abstract: A manufacturing method for an electronic component includes: a step of forming an insulating layer on an outer electrode body so as to cover the outer electrode body, the outer electrode body being formed on a chip element which forms the electronic component; and a step of removing the insulating layer in a predetermined region of the outer electrode body by applying laser light to the insulating layer in the predetermined region so as to expose the predetermined region. The insulating layer has a higher absorption coefficient for the laser light than a material forming a surface of the outer electrode body.

Abstract: A laminated inductor includes a laminate having a plurality of insulating layers, a helical coil and first and second external electrodes on an underside of the laminate. The helical coil has coiled electrodes, each coiled up in one turn, and the first and second external electrodes are connected to respective, or corresponding, ends of the helical coil. Each of the coiled electrodes of the helical coil follow a path along the periphery of one of the insulating layers and include first end located in the path and second end located outside the path. The helical coil and the first external electrode are connected to each other by a lead via conductor formed in a space that is enclosed by parts of the coiled electrodes including the first and second ends.

Abstract: A laminated inductor includes a laminate having a plurality of insulating layers, a helical coil and first and second external electrodes on an underside of the laminate. The helical coil has coiled electrodes, each coiled up in one turn, and the first and second external electrodes are connected to respective, or corresponding, ends of the helical coil. Each of the coiled electrodes of the helical coil follow a path along the periphery of one of the insulating layers and include first end located in the path and second end located outside the path. The helical coil and the first external electrode are connected to each other by a lead via conductor formed in a space that is enclosed by parts of the coiled electrodes including the first and second ends.

Abstract: A monolithic varistor includes a sintered layered body and a pair of external electrodes disposed on opposite ends of the layered body. The layered body is composed of a plurality of varistor sheets and a plurality of valistor electrodes, which are layered on one another and integrally fired. T is defined as the distance between the varistor electrodes, and Ty is defined as the distance between an outermost varistor electrode and the upper surface of the sintered layered body. Further, Tx is defined as the distance between the external electrodes and the corresponding edges of the varistor electrodes. The varistor is designed in order to satisfy one of the following three conditions: Condition (A) 1.5≦(Tx/T)≦3.0 Condition (B) (Ty/T)≧1.0 Condition (C) 1.5≦(Tx/T)≦3.0 and (Ty/T)≧1.

Abstract: A laminated-type varistor includes a laminated structure and a pair of external electrodes disposed on a surface of the laminated structure. The laminated structure includes effective sintered body layers and internal electrodes. The internal electrodes are connected to the external electrodes and are disposed apart from each other in the direction perpendicular to lamination surfaces. Each of the internal electrodes has a multilayer electrode structure in which a plurality of electrode layers are arranged in layers while an ineffective sintered body layer is disposed therebetween. The laminated-type varistor has increased maximum peak current and maximum energy and reduction in clamping voltage.