To measure high levels of direct current for overload detection and protection, designers frequently use either a current-shunt resistor or a toroidal core and Hall-effect magnetic-field sensor. Both methods suffer from drawbacks. For example, measuring 20A with a 10-mΩ resistor dissipates 4W of power as waste heat. The Hall-effect sensor delivers accurate measurements and wastes little power, but it’s an expensive approach to simple current monitoring.
This Design Idea describes an inexpensive, low-power current-measurement circuit that’s useful for measurements of modest accuracy. As a bonus, a filter inductor in a dc/dc converter’s input line can double as a current sensor for the measurement circuit. A representative ferrite core’s permeability decreases as the core nears saturation (Figure 1). The curve’s shape and values depend on the core material’s characteristics and whether the core includes an air gap.
The core’s permeability depends on the magnetic-flux level in the ferrite material, which in turn depends on the amount of current flowing through the core’s windings. This circuit uses a simple LC oscillator to measure the core’s permeability. A primary winding comprising one or more turns wound on the core carries the measurement current. A multiturn secondary winding on the core forms an inductor, L, that determines the oscillator’s resonant frequency.
In theory, any LC oscillator circuit will serve in this application, but, in practice, the current-measurement winding presents a low impedance that damps the LC-tank circuit and causes start-up and stability problems in some oscillator circuits. Of a variety of tested oscillator circuits, the design in Figure 2 offers the best performance. A number of factors affect the core’s permeability, which in turn impacts the circuit’s frequency stability and limits its applications to current-overload detection and low-accuracy current measurements.
For more detail: Low-cost current monitor tracks high dc currents
