Shunts

As resistance material itself, a special copper-nickel-manganese alloy known as manganin is used for the shunts. Manganese is ideally suited for these measurement applications because it has a very low and predictable thermal resistance coefficient and remains very stable over time.
The terminal block is normally made of brass or copper where the high current wires are connected to the shunt and where the measurement connections are located. The shunt has a position for heavy current-carrying conductors and two smaller terminals for attaching the voltage detection wires. The voltage drop is measured at the sensor terminals and thus the current through the shunt can be determined.

The rated current is the current through the shunt specified for the product that results in the specified voltage drop, or millivolt output value.
In other words, the rated current flows through the shunt when the output voltage reaches the value specified in the data sheet. This voltage serves as a reference voltage when selecting the component, because it allows the load (the decreasing power) on the element to be calculated directly (for DC current: power = current x voltage). The value is also given on the element itself and also corresponds to the maximum power for which the component is specified.

Under normal operating conditions, we recommend that engineers operate the shunt at no more than 2/3 of its rated current. On our data sheets this value is given as operating current. This safety factor ensures a long lifetime.

The shunts have a standard tolerance of 0.25% for the voltage output and are calibrated at room temperature. Many of our models are also available with tolerances of only 0.1%.

The shunt dissipates the power generated by the voltage drop across the resistive element by generating heat. This power dissipation is subject to Ohm's law and results in very low power consumption of the components, since the resistance is in the milliohm range. Nevertheless, it must be ensured that the heat generated can be dissipated. A 10 A shunt with 100 mV output voltage is operated at the maximum permissible power.
Power P = nominal current I x voltage drop U = 10 A x 100 mV = 1 Watt

Shunts work most accurately at temperatures between 30 °C and 60 °C. Care must be taken to ensure that the heat generated by the power consumption can be dissipated. Therefore, please observe the mounting instructions. Shunts can of course also be operated at lower temperatures, but this will reduce the accuracy. In this case it is recommended to calibrate the component separately for this deviating range. In principle, the temperature of the resistor elements should be limited to 125 °C for normal operation. If the temperature exceeds 145 °C, permanent damage must be expected. Please ensure suitable heat dissipation.