Due to the continuous increase of DC equipment such as photovoltaic power generation, new energy vehicles, and DC charging piles, the residual current generated contains various DC components and is becoming more and more complex. In order to solve the problem of residual current detection containing DC signal, it is more important to realize the effective detection and leakage protection of AC and DC residual current (Young et al., 2007). Literature (Takahiro and Dev, 2011) proposed a simplified magnetic modulation AC and DC residual current detection method. Literature (Ponjavic and Duric, 2007) proposed to realize the detection of AC and DC residual current through the excitation current. Literature (Xu and Min, 2009) introduced a detection and protection of pulsating DC residual current signal through hardware design. Reference (Min, 2011) combined the “State Grid Core” AC-DC hybrid leakage monitoring technology with monitoring and protection modules in the photovoltaic power generation system. Reference (Xu et al., 2015) applied full current-sensitive RCD in the charging device of electric vehicle to detect AC and DC residual current to protect equipment and personal safety. In recent years, with the in-depth research of magnetic modulation residual current detection technology, A-type residual current protector can detect residual current in the form of DC and pulsating DC. In addition, many scholars at home and abroad have conducted in-depth research on the detection method of residual current and the identification method of current waveform, which provides theoretical support for the design of residual current detection system with complex waveform (O'Shaughnessy et al., 2021).

As a weak magnetic field measurement device with good comprehensive performance (Telukunta et al., 2017), the fluxgate sensor can measure the magnetic field generated by DC and AC, and also has the advantages of good zero-point stability, small temperature drift and high resolution. It has great advantages in measuring magnetic fields.

This paper proposes an AC and DC leakage current detection method, the principle of which is shown in Figure 1.

The fluxgate current sensor is mainly composed of a magnetic ring, an energized coil, a fluxgate magnetic field sensor and an amplifying filter circuit. The fluxgate magnetic field sensor can output a voltage signal proportional to the magnetic field, and indirectly measure the magnitude of the current by measuring the magnetic induction intensity generated by the residual current.

The magnitude of the magnetic induction is related to the total current passing through the loop and the magnetic permeability in vacuum. For the residual current, the safe current through the human body is not allowed to exceed 30 mA, and the magnetic permeability of the air is very small, so the magnetic induction intensity generated by the DC residual current in the air is very weak, and it is difficult for the fluxgate sensor to measure the residual current. The value of the current, which requires the sensor to have a high sensitivity (Grim et al., 2020).

It can be seen from the above analysis that adding a magnetic core with higher magnetic permeability can improve the sensitivity of the sensor, or winding more coils on the magnetic ring, so that the weak DC residual current in the ring magnetic circuit can generate a large magnetic induction intensity. The method studied in this paper is to use a magnetic ring with high magnetic permeability to increase the ability of the magnetic focusing ring, which can more easily measure the magnetic field generated by the weak DC residual current. Ampere’s loop theorem in the presence of a magnetic medium: ∮ L B · d l = μ 0 ∑ I (1) where μ = μ r μ 0 , μ is the magnetic permeability of the magnetic ring.

H = B / μ (2)

Substitute Eq. 2 into Eq. 1 to get: ∮ H ⋅ d l = ∑ I (3)

The above formula is to analyze the current in a wire. If the wire under test is evenly wound on the magnetic ring, then the Ampere loop theorem is also satisfied when there is a magnetic medium (Velasco-Quesada et al., 2016). At this time, the formula can be transformed into: H l = N I (4) Where N is the number of turns of the coil and l is the average length of the magnetic circuit. At this time, the output of the sensor can be expressed as: V V O U T = B × k = μ N I l × k (5)

Among them, k is the proportional coefficient, which is related to the characteristics of the sensor. According to the above formula, when the magnetic permeability of the magnetic ring is constant, the output of the sensor has a linear relationship with the current to be measured (Cao et al., 2019). Due to the hysteresis characteristics of the magnetic ring, the magnetic permeability of the magnetic ring is a constant value only when it works in the linear range, so a magnetic ring with low coercivity and high saturation strength must be selected (Velasco-Quesada, 2010). In this paper, the parameters of the magnetic core are designed by means of simulation, and the maximum value of the magnetic induction intensity at the opening of the magnetic core is obtained.

In order to obtain the frequency characteristic and sensitivity of the open-loop fluxgate sensor, the sensor was measured experimentally. The experimental test principle is shown in Figure 4. The output of the arbitrary signal generator is connected to a power amplifier, and the output of the power amplifier is connected to a current-limiting resistor, and a loop is formed through a magnetic ring to simulate the leakage of different waveforms and current values. The first channel of the oscilloscope uses the current clamp meter probe to collect the current waveform in the line, and the second channel collects the output voltage of the sensor.

In the experiment: adjust the arbitrary signal generator to output 0–10 kHz sine wave sweep frequency, adjust the resistance RL to make the current value in the line 30 mA. By outputting different DC current values, the sensitivity test is carried out on the magnetic field sensor with magnetic focusing ring and the ordinary sensor. The experimental data curve is shown in Figure 5.

Fitting the data in (Figure 5A), the obtained linear formula is y = 0.15 x , that is, the sensitivity is 0.15 mV/mA, and the linearity error is 0.0205%; the same formula in (Figure 5B) is y = 1.54 x , that is, the sensitivity is 1.54 mV/mA, and the linearity error is 0.0021%. The sensitivity of the magnetic field sensor after adding the magnetic ring is 15.4 times higher than that of the sensor without the magnetic ring, and the linear error is reduced by 0.0184%.

The iron-based amorphous alloy material is selected for the open-loop magnetic focusing ring proposed in this paper, and the inner diameter of the magnetic ring is 16 mm, the outer diameter is 32 mm, the thickness is 8 mm, and the height is 3 mm through simulation. The experimental results show that the fluxgate current sensor with the open-loop magnetic concentrating ring structure can detect the residual current with a bandwidth of 6.7 kHz, a sensitivity of 1.54 mV/mA, and a linearity error of 0.0021%, which can meet the accurate detection of complex residual current waveforms.