[Problem] To provide a chip resistor that is unlikely to suffer from mounting failure and capable of readily lowering its resistance. [Solution] Disclosed is a chip resistor 1 that includes a ceramic substrate 2, a pair of bank-raising foundation sections 3 positioned on both longitudinal ends of the lower surface of the ceramic substrate 2, a pair of first electrode layers 4 that cover at least parts of the bank-raising foundation sections 3 and are positioned at a predetermined distance from each other, a resistive element 5 that is made mainly of a copper-nickel alloy to bridge the first electrode layers 4, a pair of second electrode layers 6 that cover the pair of first electrode layers 4, and an insulating protective layer 7 that covers the resistive element 5. Further, end-face electrodes 9 are positioned on both longitudinal end faces of the ceramic substrate 2. The second electrode layers 6 and end-face electrodes 9 are covered with plating layers 10-13. This chip resistor 1 is to be face-down mounted with the first and second electrodes 4, 6 positioned on a wiring pattern 21 of a circuit board 20.
[Problem] To provide a chip resistor that readily lowers its resistance and exhibits excellent manufacturing yield. [Solution] The chip resistor 10 includes a ceramic substrate 11 that is shaped like a rectangular parallelepiped. Mounted on the lower surface of the ceramic substrate 11 are a resistive element 12 that is made mainly of a low-resistance, low-TCR copper-nickel alloy, first and second electrode layers 13, 14 that form a two-layer structure and cover both longitudinal ends of the resistive element 12, and an insulating protective layer 15 for covering the remaining area of the resistive element 12. The resistive element 12 is positioned within a region inside the peripheral border of the lower surface of the ceramic substrate 11. The chip resistor 10 also includes end-face electrodes 17 that are positioned on both longitudinal end faces of the ceramic substrate 11. The second electrode layers 14 and end-face electrodes 17 are covered by plating layers 18-21. This chip resistor 10 is to be face-down mounted with both electrode layers 13, 14 positioned on a wiring pattern 31 of a circuit board 30.
A thick film circuit component has a thick film electrode interconnect which allows an electrode on a semiconductor chip and an aluminum wire to be directly bonded to each other with a sufficient bonding strength. The thick film circuit component has an insulated substrate 11 and a thick film electrode interconnect 12 disposed on the substrate. The thick film electrode interconnect 12 includes a bonding area for an aluminum wire, the bonding area comprising an Ag-Pt thick film 12a disposed as a lower layer and an Ag-Pd thick film 12b disposed as an upper layer. The bonding area comprises the Ag-Pt thick film 12a and the Ag-Pd thick film 12b, which are fused together.
A resistive element in the form of a bent metal plate is placed in a box-shaped case and has electrodes exposed out of the box-shaped case. A heat radiator in the form of a bent metal plate is also placed in the box-shaped case and has heat radiating electrodes exposed out of the box-shaped case. The resistive element and the heat radiator are held out of contact with each other and disposed in criss-cross relation to each other. The box-shaped case is filled with a cement material in surrounding relation to the resistive element and the heat radiator.
A metal plate resistor includes a resistive body comprising a metal plate, and at least a pair of electrodes joined respectively to opposite ends of the resistive body, the electrodes being made of a highly conductive metal conductor. The resistive body has a main section positioned between the electrodes and a pair of electrode sections progressively wider than the main section in directions away from the main section. The electrodes are disposed respectively beneath the electrode sections and identical in shape to the electrode sections.