A measuring resistor for high-current measurements is provided, which has a defined resistance value. The measuring resistor has a resistive layer having a sheet resistivity. The resistance value of the measuring resistor is defined by the resistive layer and is less than the sheet resistivity of the resistive layer.

A measuring resistor for high-current measurements is provided, which has a defined resistance value. The measuring resistor has a resistive layer having a sheet resistivity. The resistance value of the measuring resistor is defined by the resistive layer and is less than the sheet resistivity of the resistive layer.

The present invention concerns a layer structure comprising: a substrate having a glass or ceramic surface, a layer A at least partially covering the glass or ceramic surface of the substrate, wherein layer A comprises a glass in which at least two mutually different elements are contained as oxides, and a layer B at least partially covering the layer A. Layer B comprises: a resistance alloy having a temperature coefficient of electrical resistance less than 150 ppm/K, and optionally a glass containing at least two mutually different elements as oxides. Layer B contains not more than 20 weight percent of glass based on the total weight of layer B.

A passive two-terminal circuit element may include a resistor including a carbon-metal composite resistive element. The resistive element is configured to maintain a resistivity that fluctuates less than one tenth of an ohm per ten degree temperature change up to 400 degrees Celsius.

A passive two-terminal circuit element may include a resistor including a carbon-metal composite resistive element. The resistive element is configured to maintain a resistivity that fluctuates less than one tenth of an ohm per ten degree temperature change up to 400 degrees Celsius.

The invention relates to a composite material strip for producing an electric component, in particular a resistor, in particular a low-resistance current-measuring resistor, comprising a first material strip (4) made of a copper-containing material, in particular a copper-containing conductor material, for later forming a first connection part of the electric component and comprising a second material strip (3) for later forming a second connection part of the electric component. The first material strip (4) and the second material strip (3) are electrically and mechanically connected together along a longitudinal seam, wherein the second material strip (3) consists of an aluminum-containing material, in particular an aluminum-containing conductor material. The invention further relates to a corresponding production method and to a corresponding component.

A shunt resistor the resistive value of which can be lowered simply and easily has: a first resistive body, two base materials that sandwich the first resistive body therebetween and are joined by a welding to the first resistive body, and a second resistive body joined by a welding to the two base materials at different positions from the first resistive body. In addition, the second resistive body can come into contact with the first resistive body.

A plurality of resistors are disclosed herein. The resistor may include one or more resistive elements and a plurality of conductive portions. Openings or slots, which can be configured to adjust temperature coefficient or resistance (TCR) values of the resistor, are formed in the resistive elements. The shape, quantity, and orientation of the openings or slots can vary. In one aspect, header assemblies are provided for securing or holding pins relative to the resistors.

A resistor includes a resistive element including a first surface and a second surface facing opposite sides in a thickness direction; a protective film having electrical insulating properties disposed on the first surface; and a pair of electrodes disposed spaced apart from each other in a first direction perpendicular to the thickness direction, the pair of electrodes being configured to come into contact with the resistive element. The protective film includes a first outer edge and a second outer edge spaced apart from each other in the first direction and extending in a second direction perpendicular to both the thickness direction and the first direction. The resistive element includes a first slit and a second slit extending from the first surface through to the second surface and extending in the second direction. The first slit is located closest to the first outer edge; and the second slit is located closest to the second outer edge. As viewed in the thickness direction, a first distance from the first outer edge to the first slit and a second distance from the second outer edge to the second slit together have a length 15% or greater of a dimension of the protective film in the first direction.

A resistive composition is provided to form thick film resistors on a substrate. The resistive composition includes platinum particles and ceramic particles. The ceramic particles include alumina particles. An organic vehicle can be included to form an ink or paste for thick film process. After application to the substrate, the resistive composition is fired to form the thick film resistors, which is fully adhered to the substrate.