A lead-free glass paste, a chip resistor and a method for producing the same are provided. The lead-free glass paste includes 6-7 parts by mass of borosilicate oil, 12-21 parts by mass of aluminum oxide powder, 2-3 parts by mass of glass fiber powder, and 0.1-0.5 parts by mass of a curing agent.

A buried thermistor includes a lower substrate, an upper substrate, and a number of thermistor stacks. Each thermistor stack includes two resistor subjects. Each resistor subject includes a base layer, a medium layer, a metal layer, a resistor layer, a nanometal layer, and a conductive layer. Applicable material of the resistor layer becomes more diverse by disposing the number of thermistor stacks, and the buried thermistor shows variable thermal sensitivity.

Provided are: a temperature sensor capable of ensuring reliability and improving thermal responsiveness; and a device equipped with such a temperature sensor. The present invention is provided with: a surface-mounted heat sensitive element (10) having at least a pair of electrode parts (12a), (12b); lead parts (22a), (22b) that are electrically connected to the pair of electrode parts (12a), (12b) by welding; a holder (21) that holds and fixes the lead parts (22a), (22b); and an insulation coating part (23) that insulates at least a portion of the lead parts (22a), (22b) and the heat sensitive element (10). The lead parts (22a), (22b) are tabular metal plates and are formed of a metallic material having a melting point of not more than 1300° C.

[Object]

A method for efficiently manufacturing chip resistors is provided.

[Means]

The method includes the steps of preparing at least three conductive elongated boards 711 made of an electrically conductive material and a resistive member 702 made of a resistive material, arranging the at least three conductive elongated boards 711 apart from each other along a width direction crossing a longitudinal direction in which one of the at least three conductive elongated boards 711 is elongated, forming a resistor aggregate 703 by bonding the resistive member 702 to the at least three conductive elongated boards 711, and collectively dividing the resistor aggregate 703 into a plurality of chip resistors by punching so that each of the chip resistors includes two electrodes and a resistor portion bonded to the two electrodes.

In an embodiment a sensor device includes a sensor chip having a plurality of printed ceramic layers and unprinted ceramic layers, at least one termination layer configured to make electrical contact with an electrically conductive material, wherein the termination layer is formed at least on a top side and/or on a bottom side of the sensor chip, wherein the printed ceramic layers are at least partially printed with an electrically conductive material, and wherein an electrical resistance of the sensor chip is determined by an overlap area of the electrically conductive material or by a distance of the electrically conductive material from the termination layer and at least one damping layer directly located at at least a partial area of an outer surface of the sensor chip, wherein the damping layer includes a material which has a greater elasticity than a material of the termination layer.

A method for manufacturing a resistor is described. First and second division lines are formed in a first surface of a substrate to define device areas. First and second electrodes are formed on the first surface and respectively on the device areas. Third electrodes, fourth electrodes, and resistive layers are formed on a second surface of the substrate and respectively on the device areas. The substrate is diced from the second surface by a cutting tool to form bar structures to expose opposite first and second side surfaces of the device areas. First and second terminal electrodes are formed to respectively cover the first and second side surfaces. The bar structures are diced from the second surface by the cutting tool to separate the device areas. The cutting tool is aligned with the first and second division lines respectively while dicing the substrate and the bar structures.

A glass protective film 4 is formed such that boundaries of top surface electrodes 3a and 3b do not exist at the base of corner portions of the rectangular glass protective film 4 so as to eliminate level differences generating due to thicknesses of the electrodes. Use of such a structure may resolve the problem that when printing glass paste individually over chip elements of a chip resistor on a large substrate from which multiple chips will be obtained, corner portions of the glass protective film bleed (flow) to the outer side (dividing grooves).

A chip resistor includes an insulated substrate having a rectangular parallelepiped shape, a first front electrode and a second front electrode created on both longitudinal ends of the insulated substrate, and a resistive element making a connection between the first and second front electrodes. The resistive element is formed in a meandering shape with a first region and a second region continuing in series via a jointing section between a pair of connecting portions. Moreover, in the first region, a first trimming groove for rough adjustment is formed to elongate a current path of the resistive element. In the second region, a second trimming groove is formed for fine adjustment extending in a direction angled with respect to a straight line along a direction in which the first trimming groove extends.

A chip resistor includes a main body having opposite first and second surfaces and a peripheral surface connected between the first and second surfaces, and first and second electrode units oppositely and separately disposed on the peripheral surface. The main body includes a resistance layer having opposite top and bottom surfaces, a metallic heat dissipation layer disposed on the top surface of the resistance layer, a metallic heat conductive layer disposed on the bottom surface of the resistance layer, and an insulating unit interposed between the resistance layer and the metallic heat dissipation layer, and between the resistance layer and the metallic heat conductive layer.

A coaxial power sensor assembly configured to provide a broadband matched termination utilizing coplanar waveguide topology while simultaneously providing a source of heat energy for a surface mount chip thermistor element to measure applied input power. The coaxial thermal power sensor is comprised of a thin film resistive device on a dielectric substrate and a surface mount chip thermistor element placed in close planar proximity to the resistive device in order to maximize the heat flux via a closely coupled thermal path to the thermistor and alter the bias current through the resistance to be measured. The power sensor is intended to function from DC to 70 GHz, but the same should not be construed as a limitation.