JP2001124802A - Electric current sensor device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make separable a sensor and a signal-processing circuit and to make maintainable a specified measurement accuracy even by any combination of sensor and signal-processing circuit. SOLUTION: This device comprises a magnetic yoke 2 disposed so as to surround a current carrier 1 wherein a current to be measured flows, having a gap G1 in a part and forming a magnetic path for passing a magnetic flux induced by the current to be measured, and a magnetic sensor element 3 disposed in the gap G1 and detecting a magnetic field therein induced by the current to be measured. In a second gap G2 formed in the magnetic yoke 2, a magnetic member 11 is provided movably so as to change an insertion depth relative to the second gap G2. By changing the insertion depth of the magnetic member 11, the magnetic resistance of the magnetic path is varied, so that the output of the magnetic sensor element 3 can be calibrated for the current to be measured.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a current sensor device for measuring a relatively large current in a non-contact manner.

[0002]

2. Description of the Related Art In recent years, development of electric vehicles, photovoltaic power generation, and the like has been actively conducted in consideration of the environment. for that reason,
There is a need for a non-contact type current sensor device for accurately measuring a large DC current of several tens to several hundreds A used for them.

As a method of measuring a direct current in a non-contact manner, a method of measuring a magnetic field generated by a current with a magnetic sensor is employed. Conventionally, a Hall element has been often used as a magnetic sensor for this purpose.

[0004]

By the way, generally,
In a current sensor device using a Hall element, as a method of calibrating a measured current value, a method of adjusting a gain of a voltage amplifier that amplifies an output voltage of the Hall element is adopted.

In a current sensor device using a Hall element,
Since the sensitivity of the Hall element is low, the magnetic yoke for converging the magnetic flux generated by the current has a closed magnetic circuit structure except for the part where the Hall element is inserted. Therefore, it is very difficult to introduce a means for adjusting the magnetic field applied to the Hall element and calibrating the output of the Hall element.

Since the output voltage of the Hall element is small, the connection line from the Hall element to the signal processing circuit portion including the voltage amplifier should be as short as possible in consideration of the influence of noise. For this reason, in a current sensor device using a Hall element, a signal processing circuit including a magnetic yoke, a Hall element, and a voltage amplifier is integrally configured.

[0007] Such a conventional current sensor device using a Hall element has the following disadvantages.

(1) In a current sensor device used for an extremely wide range of use such as an automobile, whose use temperature range extends from -40 ° C. to + 150 ° C., not only a Hall element but also a voltage amplifier is constituted. Semiconductor components and other circuit components must be able to withstand the temperature range.

(2) The current sensor device measures a large current, but usually also a high voltage. Therefore, it is very disadvantageous to install a high-gain voltage amplifier or a signal processing circuit for handling a small signal near a current carrier through which such a high-voltage and large-current flows.

(3) The number of connection lines to the current sensor device is
At a minimum, the power supply voltage line, the ground line, and the device output line are three. It is desirable that the ground line paired with the device output line be separated from the ground line paired with the power supply voltage line. In addition, depending on the application, a signal line for an alarm signal indicating an abnormal operation or the like may be required as the connection line. Since all of these connecting lines must be routed to the current sensor device, the number of connecting lines increases as the number of connecting lines increases.

The above disadvantages are all caused by the fact that the Hall element and the signal processing circuit including the voltage amplifier must be integrally formed.

If the sensor portion and the signal processing circuit portion can be separated from each other and can be connected by a long connection line, it is sufficient that only the sensor portion can withstand a wide temperature range, and a semiconductor having a narrow temperature tolerance range can be used. The signal processing circuit portion composed of components and other circuit components can be installed in a place where there is little change in temperature.

In the current sensor device using the flux gate magnetic sensor, the sensor portion and the signal processing circuit portion can be separated from each other because of the high sensitivity of the flux gate magnetic sensor and the large output voltage. A single-winding fluxgate magnetic sensor is a two-terminal component. Therefore, when the sensor part and the signal processing circuit part are separated from each other in the current sensor device using the flux gate magnetic sensor, it is considered that the connection line necessary only for the signal processing circuit part does not need to be routed to the magnetic sensor part. For example, the minimum number of lead wires to the sensor part becomes two, and the number of lead wires decreases. As described above, in the current sensor device, by using the flux gate magnetic sensor and separating the sensor portion and the signal processing circuit portion, the disadvantages of the related art can be almost eliminated.

However, when the sensor portion and the signal processing circuit portion are separated from each other, if the calibration of the output as the current sensor device is left to only the gain adjustment of the voltage amplifier in the signal processing circuit portion, the following usage problems occur. Problem occurs. For example, a signal processing circuit portion calibrated specifically for one sensor portion must be used, and a signal processing circuit portion calibrated for another sensor portion cannot be used. Therefore, when handling a large number of current sensor devices, there is a high possibility that a wrong combination between the sensor portion and the signal processing circuit portion occurs. In addition, since the sensor part and the signal processing circuit part must be used as a set, there are many manufacturing restrictions.

Here, in the current sensor device, if the sensor portion and the signal processing circuit portion are interchangeable and a predetermined measurement accuracy can be maintained even in a combination of an arbitrary sensor portion and an arbitrary signal processing circuit portion, There are many benefits in production as well as in use.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has as its object to separate a sensor portion from a signal processing circuit portion, and to provide a predetermined combination of any sensor portion and any signal processing circuit portion. An object of the present invention is to provide a current sensor device capable of maintaining measurement accuracy.

[0017]

According to the present invention, there is provided a current sensor device having a gap in a part thereof, a magnetic yoke forming a magnetic path through which a magnetic flux generated by a current to be measured passes, and a gap in the gap of the magnetic yoke. And a magnetic sensor element for detecting a magnetic field in the air gap generated by the measured current,
Magnetic resistance varying means for varying the magnetic resistance of the magnetic path formed by the magnetic yoke.

In the current sensor device of the present invention, the output of the magnetic sensor element can be calibrated by changing the magnetic resistance of the magnetic path by the magnetic resistance variable means.

In the current sensor device according to the present invention, the magnetoresistive variable means includes a second gap formed in the magnetic yoke separately from the gap in which the magnetic sensor element is arranged, and a magnetic material. In the gap, a magnetic member movably provided so as to be able to change the insertion depth with respect to the second gap may be provided.

Further, in the current sensor device according to the present invention,
The magnetoresistive variable means is made of a magnetic material, forms a part of the magnetic yoke, and forms a second gap in the magnetic yoke different from the gap in which the magnetic sensor element is arranged.
May have a magnetic member movably provided so that the length of the void portion can be changed.

Further, in the current sensor device according to the present invention,
The magnetoresistive variable means has a second gap formed in the magnetic yoke separately from the gap in which the magnetic sensor element is arranged, and has a shape made of a magnetic material and having different lengths in two orthogonal directions. And a magnetic member rotatably provided in the second gap.

In the current sensor device according to the present invention,
The magnetic sensor element may be a fluxgate magnetic sensor element.

[0023]

Embodiments of the present invention will be described below in detail with reference to the drawings. [First Embodiment] FIG. 1 is a sectional view showing a main part of a current sensor device according to a first embodiment of the present invention. The current sensor device according to the present embodiment is arranged so as to surround the current carrier 1 through which the current to be measured flows, and is made of a magnetic material.
Part has a gap portion G _1, an annular magnetic yoke 2 to form a magnetic path passing the magnetic flux generated by the current to be measured flowing through the current carrier 1 is disposed in the gap portion G ₁ of the magnetic yoke 2 , and a magnetic sensor element 3 for detecting the magnetic field in the air gap portion G ₁ generated by the current to be measured flowing through the current carrier 1. The overall sectional shape of the magnetic yoke 2 is rectangular. In the present embodiment, the magnetic sensor element 3 is a flux gate magnetic sensor element.

In the current sensor device according to the present embodiment,
A magnetic yoke 2, the gap portion G ₂ separately of the second and the gap portion G ₁ to the magnetic sensor element 3 is arranged is formed. Since fluxgate magnetic sensor element is sensitive, thus, can be provided in the magnetic yoke 2, the air gap G ₂ separately of the second and the gap portion G ₁ to the magnetic sensor element 3 is arranged.

In the example shown in FIG. 1, the gap G ₁ is arranged at the lower side of the entire magnetic yoke 2, and the second gap G ₂ is arranged at the right side of the entire magnetic yoke 2. I have. In this example, the magnetic yoke 2 includes a portion 2a of the left end portion of the gap portion G ₁ to the upper end portion of the gap portion G _2, the gap portion G ₁
From the right end portion and a portion 2b to the upper end portion of the gap portion G _2. In the present embodiment, the positions of the gap G ₁ and the second gap G ₂ are not limited to the positions shown in FIG. 1, but may be arranged at convenient positions in the magnetic path formed by the magnetic yoke 2. can do.

The current sensor apparatus according to this embodiment, further, made of magnetic material, the second in the air gap G _2, moved so as to be able to vary the insertion depth for the second gap portion G ₂ A magnetic member 11 provided so as to be provided. The magnetic member 11 is movable in the direction of the arrow indicated by reference numeral 13 in FIG.

Here, the magnetic member 11 is connected to the second gap G _2.
An example of a method of movably providing the inside will be described. In this example, the magnetic member 11 has a bolt structure obtained by cutting a thread groove on an outer peripheral portion of a columnar magnetic body.
In the second in the air gap G _2, for example made of resin,
A nut-structured holding portion 12 is provided with which a bolt-shaped magnetic member 11 is screwed. In this method, the magnetic member 11
The by rotating, it is possible to vary the depth of insertion of the second magnetic member 11 with respect to the gap portion G _2. After the position adjustment of the magnetic member 11, the magnetic member 11 and the holding portion 12 may be fixed by bonding or the like.

The method for providing movable magnetic member 11 into the second gap portion G ₂ is may be in other ways not limited to the above method. As another method, for example, the magnetic member 11 is not formed in a bolt structure, the holding portion 12 is not formed in a nut structure, the magnetic member 11 and the holding portion 12 are shaped to fit each other, and the holding portion 12 is heated. There is a method in which the magnetic member 11 is press-fitted, adjusted in position and fixed.

The second gap G ₂ , the magnetic member 11 and the holding portion 12 correspond to the magnetoresistive variable means in the present invention, and change the magnetic resistance of the magnetic path formed by the magnetic yoke 2.

Next, the operation of the current sensor device according to this embodiment will be described. In FIG. 1, a magnetic flux generated by a current to be measured flowing through a current carrier 1 in a direction perpendicular to the paper surface of FIG.
It passes through the magnetic yoke 2. As a result, in the gap portion G ₁ of the magnetic yoke 2, the magnetic field corresponding to the current to be measured is generated. Then, by the magnetic sensor element 3 disposed in the gap portion G ₁ of the magnetic yoke 2, the magnetic field in the gap portion G ₁ is detected,
Based on the output of the magnetic sensor element 3, the current to be measured is measured in a non-contact manner.

According to the current sensor apparatus of the present embodiment, by changing the insertion depth of the second magnetic member 11 with respect to the gap portion G _2, vary the magnetic resistance of the magnetic path formed by the magnetic yoke 2 Therefore, it is possible to calibrate the output of the magnetic sensor element 3 with respect to the measured current flowing through the current carrier 1. The configuration and operation of the entire current sensor device including the signal processing circuit will be described after the description of the other embodiments.

[Second Embodiment] FIG. 2 is a sectional view showing a main part of a current sensor device according to a second embodiment of the present invention. The current sensor device according to the present embodiment has a first
Similar to the embodiment includes a magnetic yoke 2 having a void portion G ₁ part, and a magnetic sensor element 3 disposed in the gap portion G ₁ of the magnetic yoke 2.

In the current sensor device according to the present embodiment,
Part of the magnetic yoke 2 is made of a magnetic material and is movably provided.
It is constituted by the magnetic member 2c which is cut. In FIG.
In the example shown, the magnetic member 2c is provided on the entire surface of the magnetic yoke 2.
The upper right part of the right side
Swelling. In this example, the magnetic yoke 2 is
G₁From the left end of the upper part of the entire magnetic yoke 2
A portion 2a up to the vicinity of the right end, and a gap G₁From the right end of
Of the magnetic yoke 2 up to the vicinity of the central portion of the right side portion.
A portion 2b and the above-described magnetic member 2c are included. Magnetic member 2
c is the direction of the arrow indicated by reference numeral 23 in FIG.
That is, it can be moved up and down. Part 2a and magnetic
The members 2c are connected to each other regardless of the position of the magnetic member 2c.
It comes into contact. On the other hand, the portion 2b and the magnetic member
2c, the second gap G _TwoIs formed and this
2 gap G_TwoDepends on the position of the magnetic member 2c.
It is changing. In this embodiment,
And the gap G₁And the second gap G_TwoThe position of is shown in FIG.
Position in the magnetic path formed by the magnetic yoke 2
It can be arranged in a good position.

Here, an example of a method of movably providing the magnetic member 2c will be described. In this example, guide members 21 and 22 made of, for example, resin and guiding the magnetic member 2c are provided along the moving direction of the magnetic member 2c. The guide member 21 is fixed to each inner peripheral portion of the portion 2a and the portion 2b. The guide member 22 is fixed to an outer peripheral portion of the portion 2b. The magnetic member 2c is sandwiched and held by the guide members 21 and 22, and is movable in the vertical direction. After the position adjustment of the magnetic member 2c, the magnetic member 2c and the guide members 21 and 22 may be fixed by bonding or the like. The method of providing the magnetic member 2c so as to be movable is as follows.
The method is not limited to the above method, and another method may be used. Magnetic member 2c
Corresponds to the magnetoresistive variable means in the present invention.

[0035] In this embodiment, by changing the position of the magnetic member 2c, the length of the second gap portion G ₂ is changed, the magnetic resistance of the magnetic path formed by the magnetic yoke 2 is changed, the current carrier Calibration of the output of the magnetic sensor element 3 with respect to the current to be measured flowing through 1 is enabled.

Other configurations, operations and effects of the present embodiment are the same as those of the first embodiment.

[Third Embodiment] FIG. 3 is a sectional view showing a main part of a current sensor device according to a third embodiment of the present invention. The current sensor device according to the present embodiment has a first
Similar to the embodiment includes a magnetic yoke 2 having a void portion G ₁ part, and a magnetic sensor element 3 disposed in the gap portion G ₁ of the magnetic yoke 2.

In the current sensor device according to the present embodiment,
A magnetic yoke 2, the gap portion G ₂ separately of the second and the gap portion G ₁ to the magnetic sensor element 3 is arranged is formed. In the example shown in FIG. 3, the gap G ₁ is disposed on the lower side of the entire magnetic yoke 2, and the second gap G ₂ is
It is arranged on the right side of the whole. In this example,
The magnetic yoke 2 includes a portion 2a of the left end portion of the gap portion G ₁ to the upper end portion of the gap portion G _2, and a portion 2b of the right end portion of the gap portion G ₁ to the upper end portion of the gap portion G _2. In this embodiment, the position of the gap portion G ₁ and the second gap portion G ₂ is,
Not only the position shown in FIG. 3 but also a convenient position in the magnetic path formed by the magnetic yoke 2 can be provided.

In the current sensor device according to the present embodiment,
Furthermore, made of magnetic material, it has a different shape lengths in two orthogonal directions, and a magnetic member 31 which is rotatably provided in the second air gap portion G _2. Magnetic member 31
Is formed in, for example, a rectangular parallelepiped shape, and is rotatable in a direction indicated by an arrow in the drawing around an axis extending through a central portion in the longitudinal direction and extending in a direction orthogonal to the longitudinal direction.

Here, the magnetic member 31 is connected to the second gap G _2.
An example of a method of rotatably providing the inside will be described. In this example, the magnetic member 31 is housed in a cylindrical rotating member 32 made of, for example, resin. In the second in the air gap G _2, for example made of resin, the rotary member 32
Is provided for rotatably holding. In this method, the rotating member 3 held by the holding portion 33
By rotating ₂ , the magnetic member 31 can be rotated in the second gap G2. Magnetic member 3
After the adjustment of the rotation position, the rotation member 32 and the holding portion 33 may be fixed by bonding or the like. The method of providing rotatably in the magnetic member 31 within the second gap portion G ₂ is may be in other ways not limited to the above method. The second gap G ₂ , the magnetic member 31, the rotating member 32, and the holding portion 33 correspond to the variable magnetic resistance in the present invention.

[0041] In this embodiment, by changing the rotational position of the magnetic member 31 in the second gap portion G _2,
Effective gap length is changed in the second gap portion G _2, as a result, the magnetic resistance of the magnetic path formed by the magnetic yoke 2 is changed, the magnetic sensor element 3 with respect to the measured current flowing through the current carrier 1 The output can be calibrated.

According to the current sensor device of the present embodiment, the movable portion (rotating member 32) for varying the magnetic resistance of the magnetic path formed by the magnetic yoke 2 is almost the outer diameter of the magnetic yoke 2. Since it does not protrude, it is possible to prevent an unintended output fluctuation due to an impact on the movable part or the like.

Other configurations, operations, and effects of the present embodiment are the same as those of the first embodiment.

Next, with reference to FIGS. 4 and 5, the configuration and operation of the entire current sensor device common to the first to third embodiments will be described.

FIG. 4 is an explanatory diagram showing the overall configuration of the current sensor device. As shown in this figure, the current sensor device processes a sensor head 41 which is a sensor part including the magnetic yoke 2, the magnetic sensor element 3, and the magnetic resistance variable means, and processes an output signal of the magnetic sensor element 3, A signal processing circuit 42 that outputs a signal corresponding to the current to be measured.

Although FIG. 4 shows the configuration including the magnetic member 31 of the third embodiment as the magnetoresistive variable means, the magnetoresistive variable means has the configuration of the first or second embodiment. There may be.

The signal processing circuit 42 has an input terminal 43 for inputting an output signal of the magnetic sensor element 3 of the sensor head 41.
And an output terminal 44 for outputting a signal corresponding to the measured current.
And a circuit output adjusting mechanism 45 for adjusting an output signal with respect to an input signal.

The sensor head 41 and the signal processing circuit 42 are separate components, and the magnetic sensor element 3 of the sensor head 41
And the input terminal 43 of the signal processing circuit 42 are connected via a connection line 46 of a required length.

FIG. 5 is a block diagram showing an example of a circuit configuration of the current sensor device shown in FIG. In this example, the magnetic sensor element 3 in the sensor head 41 is
1 and a sensor coil 102 composed of at least one coil wound around the magnetic core 101. The sensor head 41 has an inductance element 104 connected in series with the sensor coil 102 for detecting a change in the inductance value of the sensor coil 102. One end of the inductance element 104 is connected to the other end of the sensor coil 102, and the other end is grounded.

On the other hand, the signal processing circuit 42 has one end connected to one end of the sensor coil 102 and the other end grounded.
A voltage generated at both ends of the inductance element 104, which is connected to an AC current supply unit 103 that supplies an AC drive current to the sensor coil 102 so that 01 reaches a saturation region, and a connection point between the sensor coil 102 and the inductance element 104 And a differentiating circuit 105 for differentiating
5, a positive peak hold circuit 106 for holding the positive peak value of the output signal, and a negative peak hold circuit 107 for holding the negative peak value of the output signal of the differentiating circuit 105.
An adder circuit 108 for adding the value held by the positive peak hold circuit 106 and the value held by the negative peak hold circuit 107;
And an output terminal 109 for outputting the output signal of

In the current sensor device shown in FIG. 5, the excitation current of the sensor coil 102 supplied from the AC current supply unit 103 is applied to the inductance element 104 and the differentiation circuit 1.
05, two spike-shaped voltage signals having opposite polarities, representing the positive and negative peak values of the excitation current. Each peak value of the positive and negative spike-shaped voltage signals is held by a positive peak hold circuit 106 and a negative peak hold circuit 107, added by an adder circuit 108, and output as an output signal from an output terminal 109.

In the current sensor device shown in FIG. 4, in the sensor head 41, the output is adjusted by the magnetoresistive variable means so that the output signal of the predetermined magnetic sensor element 3 can be obtained for the predetermined current to be measured. That is, calibration is performed. On the other hand, in the signal processing circuit 42, output adjustment, that is, calibration is performed in advance by the circuit output adjustment mechanism 45 so that a predetermined output signal is obtained for a predetermined input signal. Therefore, the sensor heads 41 and the signal processing circuits 42 are calibrated similarly by calibrating the plurality of sensor heads 41 and calibrating the plurality of signal processing circuits 42 similarly.
Irrespective of the combination, the relationship between the measured current and the output signal of the signal processing circuit 42 becomes constant.

Therefore, according to the current sensor device according to each embodiment of the present invention, the calibrated sensor heads 41 and the calibrated signal processing circuits 42 are compatible with each other. Compatibility as a current sensor device is ensured by a combination of arbitrary signal processing circuits 42.

As described above, according to the current sensor device according to each embodiment of the present invention, the output of the magnetic sensor element 3 is changed by changing the magnetic resistance of the magnetic path of the magnetic yoke 2 by the magnetic resistance variable means. Calibration becomes possible. Therefore, according to the current sensor device according to each embodiment of the present invention, the sensor head 41 and the signal processing circuit 42 can be separated, and the predetermined measurement can be performed even in a combination of any sensor head 41 and any signal processing circuit 42. Accuracy can be maintained.

According to the current sensor device according to each embodiment of the present invention, the sensor head 41 and the signal processing circuit 4
Since they can be separated from each other, they can be connected by a long connection line 46. As a result, the sensor head 4
It is sufficient that only 1 can withstand a wide temperature range, and the signal processing circuit 42 composed of semiconductor components and other circuit components having a narrow temperature tolerance range can be installed in a place where there is little change in temperature. In addition, a signal processing circuit 42 for handling minute signals
Can be arranged at a distance from the current carrier 1 through which the non-measured current of high voltage and large current with a lot of noise flows. From these facts, the current sensor device according to each embodiment of the present invention enables current measurement with high accuracy, and is most suitable for automobile use and the like.

In the current sensor device according to each embodiment of the present invention, when a flux gate magnetic sensor element is used as the magnetic sensor element 3, the minimum number of lead wires to the sensor head 41 is two. , The number of leading lines can be reduced.

The present invention is not limited to the above embodiments, but can be variously modified. For example, an element other than the flux gate element can be used as the magnetic sensor element.

[0058]

As described above, according to the current sensor device of the present invention, the output of the magnetic sensor element can be calibrated by changing the magnetic resistance of the magnetic path by the magnetic resistance variable means. The sensor portion including the yoke and the magnetic sensor element can be separated from the signal processing circuit portion, and the predetermined measurement accuracy can be maintained even in a combination of any sensor portion and any signal processing circuit portion. Play.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a main part of a current sensor device according to a first embodiment of the present invention.

FIG. 2 is a sectional view showing a main part of a current sensor device according to a second embodiment of the present invention.

FIG. 3 is a sectional view showing a main part of a current sensor device according to a third embodiment of the present invention.

FIG. 4 is an explanatory diagram showing an overall configuration of a current sensor device common to each embodiment of the present invention.

5 is a block diagram showing an example of a circuit configuration of the current sensor device shown in FIG.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 current carrier 2 magnetic yoke G ₁ void portion G ₂ second void portion 3 magnetic sensor element 11 magnetic member 1
2. Holding part.

Claims (5)

[Claims] A magnetic yoke having a gap in a part thereof and forming a magnetic path through which a magnetic flux generated by the measured current passes; and a magnetic yoke arranged in the gap of the magnetic yoke and generated by the measured current. A current sensor device comprising: a magnetic sensor element for detecting a magnetic field in the air gap; and a magnetoresistive variable means for varying a magnetic resistance of a magnetic path formed by the magnetic yoke. 2. The magnetic resistance varying means, comprising: a second gap formed in the magnetic yoke separately from a gap in which the magnetic sensor element is arranged; 2. The current sensor device according to claim 1, further comprising: a magnetic member movably provided so that an insertion depth with respect to the second gap portion can be changed. 3. The magnetic resistance varying means is made of a magnetic material, forms a part of the magnetic yoke, and is different from a gap portion in which the magnetic sensor element is arranged.
2. The current sensor according to claim 1, further comprising: a magnetic member formed in the magnetic yoke, wherein the magnetic member is movable so that the length of the second gap can be changed. apparatus. 4. The magnetic resistance variable means includes: a second gap formed in the magnetic yoke separately from a gap in which the magnetic sensor element is arranged; The current sensor device according to claim 1, further comprising: a magnetic member having a shape having a different length and rotatably provided in the second gap. 5. The magnetic sensor element according to claim 1, wherein the magnetic sensor element is a flux gate magnetic sensor element.
The current sensor device according to any one of the above.