JP2017003283A - Current sensor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a current sensor that exhibits an improved current detection accuracy by effective suppression of generation of an eddy current and by reduction of noise caused by a stray capacitance from a current path.SOLUTION: A current sensor 1 includes: a ground conductor 11 on a surface of a substrate; and a magnetic sensor 12 between a current path 10 as a measurement target and the ground conductor 11, having a main sensitivity shaft 30 parallel to the surface of the substrate 14, the ground conductor 11 having a suppression part 13 made of a long and thin hole suppressing the flow of the eddy current 50 in a closed region surrounded by a conductor region forming the ground conductor 11, and the direction of the main sensitivity shaft 30 of the magnetic sensor 12 being along the longer direction of the suppression part 13.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a current sensor that detects a current to be measured flowing through a current path by detecting magnetism generated by the current to be measured.

  In recent years, relatively large currents are handled particularly in the fields of motor drive technology in electric vehicles and hybrid cars, and current sensors using magnetoresistive elements that can measure large currents without contact are used for these applications. It has been.

  As such a current sensor, there is one that detects a change in a magnetic field caused by a current to be measured using a magnetic detection element. In such a current sensor, a conductive shield layer is formed on a substrate on which a magnetic sensor for detecting a magnetic flux generated by a current flowing through the bus bar is mounted, and the shield layer is grounded. Thereby, the detection error of the magnetic sensor due to the stray capacitance between the bus bar and the magnetic sensor is prevented, and the current detection accuracy is enhanced.

  On the other hand, when a grounding conductor with such a shield layer is provided on the board, when the amount of current flowing through the bus bar changes and the magnetic flux passing through the magnetic sensor changes, the shield layer is designed to cancel the change in the magnetic flux. Eddy current flows. The magnetic flux generated by this eddy current passes through the magnetic sensing surface of the magnetic sensor, the level of magnetic detection by the magnetic sensor increases or decreases, and the current detection accuracy decreases. Therefore, a structure of a ground conductor and a substrate that suppresses generation of eddy current has been considered.

JP 2011-112510 A JP 2008-545964 A

  Patent Documents 1 and 2 disclose a configuration that suppresses eddy currents by providing slits in the shield layer. However, since the direction of the magnetic field detected by the magnetic sensor is perpendicular to the substrate, it is necessary to extend the slit to the end of the shield layer so that the magnetic sensor is not surrounded by the shield layer. As described above, the shield layer is provided to suppress the noise caused by the stray capacitance between the bus bar and the magnetic sensor, so if an excessively large cavity is provided between the detection element and the current path, the noise There is a problem that it cannot be effectively suppressed.

  The present invention has been made in view of such circumstances, and an object thereof is to effectively suppress the generation of eddy currents while suppressing noise caused by stray capacitance from the current path, thereby detecting current. The object is to provide a current sensor with improved accuracy.

  A current sensor according to the present invention includes a ground conductor provided on a surface of a substrate, and a magnetic sensor provided between a current path to be measured and the ground conductor. A main sensitivity axis parallel to the surface, and the grounding conductor has a restraining portion composed of an elongated hole that restrains the flow of eddy current in a closed region surrounded by a conductor region forming the grounding conductor. The direction of the main sensitivity axis of the magnetic sensor is along the longitudinal direction of the suppressing portion.

According to this configuration, since the main sensitivity axis of the magnetic sensor is set in a direction parallel to the surface of the substrate, the magnetic sensor is not affected by the combined magnetic flux generated by the entire eddy current flowing around the outside of the magnetic sensor. In addition, since the main sensitivity axis of the magnetic sensor is along the direction of the suppression portion, no eddy current is generated in the direction perpendicular to the main sensitivity axis direction of the magnetic sensor in the vicinity of the magnetic sensor. Magnetic flux in the sensitivity axis direction is not generated.
On the other hand, since the suppression portion is formed in a closed region surrounded by the conductor region, the hole formed in the ground conductor can be made small, the room for noise generation due to stray capacitance is minimized, and the eddy current is effectively reduced. Flow can be suppressed. In other words, in the past, since the main sensitivity axis of the magnetic sensor was assumed to be perpendicular to the surface of the substrate, the effect of the combined magnetic flux generated by the entire eddy current was considered. It was necessary to drill long holes.
On the other hand, in the present invention, the main sensitivity axis of the magnetic sensor is made parallel to the surface of the substrate, and not only the combined magnetic flux generated by the entire eddy current but also the magnetic flux generated by the eddy current in the vicinity of the sensor. Since the influence is also taken into consideration, the occurrence of errors due to eddy currents can be suppressed with a shorter hole than before. Further, according to this configuration, since the direction in which the suppressing portion extends is along the direction of the main sensitivity axis, the eddy current generated on the ground conductor is prevented from crossing at a position along the main sensitivity axis. . Therefore, it is possible to prevent a decrease in current detection accuracy caused by the eddy current crossing the main sensitivity axis. Further, according to this configuration, since the elongated hole is formed in the ground conductor, the flow of the eddy current is suppressed by the hole, thereby suppressing the decrease in the current detection accuracy.

  Suitably, as for the current sensor which concerns on this invention, the said suppression part is extended in the direction orthogonal to the current direction of the said current path.

  Preferably, the magnetic sensor according to the present invention has a sub-sensitivity axis orthogonal to the main sensitivity axis, and the suppression unit includes the first suppression unit extending in the predetermined direction and the predetermined direction. The second suppression unit extends in a direction orthogonal to the first suppression unit, and the first suppression unit and the second suppression unit intersect each other.

  According to this configuration, since the suppression unit along the main sensitivity axis and the suppression unit along the sub-sensitivity axis are provided, crossing of eddy currents on the magnetic sensor can be suppressed by each suppression unit.

  Suitably, the said suppression part which concerns on this invention is arrange | positioned so that it may overlap with the said magnetic sensor seeing from the normal line direction of the surface of a grounding conductor.

  According to this configuration, since the position of the suppression unit is associated with the position of the magnetic sensor, the crossing of eddy currents at the position corresponding to the position of the magnetic sensor can be suppressed.

  Suitably, the said suppression part which concerns on this invention is provided in the center of the width direction of the said current path.

  According to this configuration, since the suppression unit is provided at a position close to the current path in the ground conductor, the suppression unit is disposed at a position where the magnetic field to be measured is large, and thus the eddy current is also large. It is possible to effectively suppress the eddy current from crossing the position corresponding to the magnetic sensor.

  ADVANTAGE OF THE INVENTION According to this invention, generation | occurrence | production of an eddy current can be suppressed effectively, and the current sensor which the current detection accuracy improved by it can be provided.

It is a perspective view which shows the current path of the current sensor of embodiment of this invention, and the positional relationship of a magnetic sensor. It is a top view which shows the positional relationship of an electric current path and a magnetic sensor. It is side surface sectional drawing which shows the positional relationship of an electric current path and a magnetic sensor. It is a top view explaining a main sensitivity axis | shaft with the positional relationship of an electric current path and a magnetic sensor. It is a figure explaining the flow of the eddy current of embodiment of this invention. It is a figure explaining the eddy current 50 in case a suppression part is not provided. It is a figure explaining the case where a control part is provided. It is side surface sectional drawing which shows the positional relationship of the electric current path concerning other embodiment, and a magnetic sensor. It is a top view explaining a main sensitivity axis and a subsensitivity axis. It is a figure explaining the flow of an eddy current. It is a figure explaining the case where the 2nd suppression part is provided.

  Hereinafter, a current sensor according to an embodiment of the present invention will be described. FIG. 1 is a perspective view showing the positional relationship between the current path 10 and the magnetic sensor 12. In order to measure the magnitude of the current flowing through the current path 10, the current sensor 1 is disposed at a predetermined location of the current path 10. The current sensor 1 includes a ground conductor 11, a magnetic sensor 12, a suppressing unit 13, a substrate 14, and a magnetic shield 15.

The current path 10 is also called a bus bar, is made of a material having good conductivity such as copper (Cu), and is formed in a flat plate shape having a width wider than the thickness. The material of the current path 10 is not limited to copper (Cu) and may be any material having good conductivity, such as aluminum (Al). One end of the current path 10 is attached to the switching circuit side of the vehicle equipment, and the other end is attached to the connection terminal on the motor side.
When the power is turned on, a large current for supplying power flows through the current path 10 and this becomes the current to be measured. Since the present invention is not particularly limited to vehicle applications, the present invention can also be applied to current paths used in other power supply devices.

  The arrangement of each element constituting the current sensor 1 will be described. A substrate 14 is disposed at an opposing position in parallel to the flat plate constituting the current path 10, and the ground conductor 11 is disposed so as to overlap the substrate 14. The position of the ground conductor 11 is opposite to the substrate 14 with respect to the current path 10. A magnetic sensor 12 is provided on the opposite side of the substrate 14 to the ground conductor 11, and a suppression unit 13 is provided on the ground conductor 11. Magnetic shields 15 are provided on both sides of the ground conductor 11 and the substrate 14 in a plane direction perpendicular to the surfaces constituting the ground conductor 11 and the substrate 14.

  The ground conductor 11 is also called a shield layer, extends in a planar shape, is made of a metal provided on the surface of the substrate 14, and is grounded. As a result of stray capacitance that can occur between the current path 10 and the substrate 14, charges are accumulated on the substrate 14 side, and the ground conductor 11 collects accumulated charges by being placed on the substrate 14. Since it is grounded, the generation of electrostatic induction noise is suppressed by discharging electric charges to the outside.

The magnetic sensor 12 is provided between the current path 10 to be measured and the ground conductor 11. The magnetic sensor 12 is an element that detects a magnetic field generated when a current flows through the current path 10, and uses, for example, a magnetic detection element (GMR (Giant Magneto Resistive) element) using a giant magnetoresistance effect. . Since this GMR element has a property that the resistance value of the GMR element changes according to the change of the magnetic field, the magnetic sensor 12 calculates the measured current flowing in the current path 10 from the change of the resistance value. Thus, the current to be measured flowing in the current path 10 can be measured.
Note that not all of the magnetic sensor 12 is formed of a GMR element, but the magnetic sensor 12 itself is an IC package, which includes a GMR element portion. The arrangement of the magnetic sensor 12 and the ground conductor 11 is not limited to the above, and the ground conductor 11 may be provided between the current path 10 and the magnetic sensor 12.

  The ground conductor 11 is provided with a suppressing portion 13. That is, the ground conductor 11 has a suppression portion 13 formed of an elongated hole that suppresses the flow of eddy current in a closed region surrounded by the conductor region that forms the ground conductor 11. A planar region formed by the suppression unit 13 is surrounded by the ground conductor 11, and the end of the suppression unit 13 does not extend to the end of the ground conductor 11. The restraining part 13 extends on the line, and its end is inside a closed plane formed by the ground conductor 11. The suppression unit 13 is disposed so as to overlap the magnetic sensor 12 when viewed from the normal direction of the surface of the ground conductor 11, and is provided at the center in the width direction of the current path 10.

  The suppression unit 13 is a slit, groove, or hole provided in the ground conductor 11, and may be configured as a through hole or a non-penetrating groove. The width of the suppression unit 13 is larger than the width of the magnetic sensor 12, and the magnetic sensor 12 is disposed in the width of the groove of the suppression unit 13. Thereby, the influence of the eddy current described later can be reduced. The groove of the suppressing unit 13 is slightly longer than one side of the IC package constituting the magnetic sensor 12 and is set to protrude slightly from the IC package.

  The substrate 14 uses a generally well-known double-sided printed wiring board, and a metal foil such as copper (Cu) provided on the base substrate is patterned on a base substrate made of epoxy resin containing glass, A circuit pattern for forming a circuit is formed. In addition, although the printed wiring board which consists of an epoxy resin containing glass is used for the board | substrate 14, it is not limited to this, For example, a ceramic wiring board and a flexible wiring board may be sufficient.

  The magnetic shield 15 is integrally formed of a magnetic material with a substantially U-shaped cross section, and is installed inside the housing with the opening facing upward. The magnetic shield 15 is not in contact with the current path 10. The magnetic shield 15 induces a magnetic flux in a region surrounded by a substantially U-shaped cross section, and has resistance against an external magnetic field that causes disturbance. For this reason, even in an installation environment in which the influence of an external magnetic field due to the presence of an adjacent current path or the like is a concern, it can be used with a certain degree of good detection accuracy. The magnetic shield 15 is not limited to the above, and may be composed of two flat plates and may be arranged so as to sandwich the current path 10 and the substrate 14.

FIG. 2 is a plan view showing the positional relationship between the current path 10 and the magnetic sensor 12. When viewed from the opening side of the magnetic shield 15, the ground conductor 11 is at the forefront, and the suppressing portion 13 is provided at the center of the ground conductor 11. Although the substrate 14 is behind the ground conductor 11, it is not shown because it is behind the ground conductor 11. The magnetic sensor 12 is disposed behind the substrate 14 as indicated by a dotted line. Further behind, a current path 10 to be measured is arranged. Each of the above arrangements is sandwiched from the side by the magnetic shield 15.

  FIG. 3 is a side sectional view showing the positional relationship between the current path 10 and the magnetic sensor 12. FIG. 3 also shows each configuration described in FIG. 1 and FIG. 2, but unlike FIG. 1 and FIG. 2, the positional relationship between the ground conductor 11 and the substrate 14 is shown. As shown in FIG. 2, the substrate 14 located behind the ground conductor 11 when viewed from above is disposed so as to overlap the ground conductor 11.

  The suppression unit 13 is also shown from the side, and the slit of the suppression unit 13 extends along the width of the magnetic sensor 12. On the other hand, since the suppression portion 13 spreads linearly, the width of the current path 10 on the traveling direction side is small, and it is shown in FIG. 3 that the ground conductor 11 extends beyond the suppression portion 13. . Further, the magnetic sensor 12 is mounted on the substrate 14 via the mounting portion 21 on the current path 10 side of the substrate 14.

  Here, since the GMR element is used as the magnetic sensor 12, the main sensitivity axis 30 which is one of the sensitivity axes of the magnetic sensor 12 is perpendicular to the right direction of FIG. The direction is along the surface of the ground conductor 11 and the substrate 14. Here, the sensitivity axis is the direction of the magnetic field that maximizes the detection sensitivity of the magnetic field detected by the magnetic sensor 12. The sensitivity influence axis (sub-sensitivity axis) is the direction of the magnetic field that affects the detection sensitivity in a direction that is not parallel to the sensitivity axis. In the present invention, “substantially parallel” and “substantially antiparallel” are concepts including completely parallel and completely antiparallel, respectively. When a Hall element is used as the magnetic sensor 12, the sensitivity axis is not the direction indicated by the main sensitivity axis 30 but a direction perpendicular to the ground conductor 11 and the surface of the substrate 14.

FIG. 4 is a plan view for explaining the main sensitivity axis 30 together with the positional relationship between the current path 10 and the magnetic sensor 12. The direction of the main sensitivity axis 30 described from the side sectional view in FIG. 3 will be described with reference to a plan view in FIG.
The direction 40 is the direction of the current passing through the current path 10. As shown in FIG. 4, the direction of the main sensitivity axis 30 is right when the direction 40 in which the current travels is upward. Thus, the magnetic sensor 12 has the main sensitivity axis 30 along a predetermined direction. Specifically, the direction of the main sensitivity axis 30 of the magnetic sensor 12 is along the longitudinal direction of the suppressing unit 13. And the suppression part 13 is extended in this predetermined direction. That is, the suppression unit 13 extends in a direction orthogonal to the direction 40 in which the current in the current path 10 flows.

  FIG. 5 is a diagram for explaining the flow of eddy currents 50, 51, 52. As shown in FIG. 4, the current path 10, the ground conductor 11, and the magnetic sensor 12 are arranged, and when a current flows along the direction 40, a magnetic field is generated so as to wind around the direction 40. On the other hand, since the magnitude of the current is not constant, the magnitude of the magnetic flux density generated by the current also changes according to the change in the magnitude of the current.

  When the suppressing portion 13 is not provided in the ground conductor 11, an eddy current 50 is generated in a direction that cancels the change in the magnetic flux density. The eddy current 50 crosses the position of the suppression unit 13, and therefore flows across the position above the magnetic sensor 12, and the magnetic field generated as a result of this eddy current 50 is detected by the magnetic sensor 12. .

Therefore, since the suppression unit 13 is provided in the present embodiment, the eddy current 50 can be suppressed from flowing across the suppression unit 13 as the ground conductor 11 is separated at the position of the suppression unit 13. . As a result, the eddy current 51 and the eddy current 52 flow in the ground conductor 11 while avoiding the position of the suppression unit 13.
That is, the eddy current 51 and the eddy current 52 do not cross the suppression unit 13 and flow in opposite directions with respect to the suppression unit 13. Therefore, in the magnetic sensor 12 corresponding to the position of the suppression unit 13, the effect of the magnetic field generated by the eddy current 51 and the eddy current 52 is reduced or canceled at least with respect to the main sensitivity axis 30.

  Further, even if a virtual stray capacitance is generated between the suppression portions 13 and a current may flow, since the suppression portion 13 does not extend to the end of the ground conductor 11, The flow of the current 52 is not completely cut off, and the position of the end portion of the ground conductor 11 becomes an escape path. As a result, even if a virtual stray capacitance occurs, the potential difference is prevented from becoming too large across the suppression unit 13, and it is more effective that the eddy current 51 and the eddy current 52 flow through the suppression unit 13. Can be prevented. On the other hand, when a GMR element is used for the magnetic sensor 12, the sensitivity axis is a direction along the main sensitivity axis 30. Therefore, even if the eddy current 51 and the eddy current 52 flow at the end of the suppression unit 13, the magnetic sensor The sensitivity of 12 is not adversely affected.

FIG. 6 is a diagram illustrating the eddy current 50 when the suppressing unit 13 is not provided. In FIG. 6, the magnitude of the eddy current flowing on the ground conductor 11 is represented by contour lines. When the suppression unit 13 is not provided, the current density flowing through the position 60 is the smallest. At the position 60, for example, an eddy current 50 of 0.875 MA / m ² or less flows. An eddy current 50 larger than that flows at the position 61, for example, an eddy current 50 of 2.625 to 3.5 MA / m ² or less flows. In the outer position 62, an eddy current 50 larger than that flows, for example, an eddy current 50 of 3.5 MA / m ² or more flows.

  FIG. 7 is a diagram illustrating a case where the suppressing unit 13 is provided. In FIG. 7, as in FIG. 6, the magnitude of the eddy current flowing on the ground conductor 11 is represented by contour lines. In FIG. 7, by providing the suppression unit 13, the eddy current 51 and the eddy current 52 flow as shown in FIG. 5, and as a result, the contoured current density becomes large as shown in FIG. 7. .

At the position 70, for example, the current density is 62.5 kA / m ² or less. At the position 71, the current density is higher than that, for example, a current density of 62.5 to 100 kA / m ² or less. At the outer position 72, the current density is higher than that, for example, a current density of 100 kA / m ² or more. Although not shown by the contour lines, the current density is the same as that at the position 71 near the center of the suppression unit 13, while the current density is large at both ends of the suppression unit 13.

  By providing the suppression unit 13 in this manner, the magnitude of the eddy currents 51 and 52 as a whole is reduced as compared with the eddy current 50, and the eddy currents 51 and 52 cannot pass through the position of the suppression unit 13.

With the configuration as described above, since the suppression portion 13 is provided inside the planar region of the ground conductor 11, the eddy current 50 does not flow across the hole or groove provided by the suppression portion 13. Therefore, the flow of the eddy current 50 becomes a flow like the eddy current 51 and the eddy current 52 by forming a flow avoiding the suppression unit 13.
Although the eddy current 50 or the eddy current 51 and the eddy current 52 are generated by the temporal change in the magnitude of the current flowing through the current path 10, the eddy current 51 and the eddy current 52 do not pass through the suppressing unit 13. .

  Further, the position of the end portion of the ground conductor 11 serves as an escape path even when a virtual stray capacitance is generated between the suppression portions 13 and a current may flow. As a result, even if a virtual stray capacitance occurs, the potential difference is prevented from becoming too large across the suppression unit 13, and it is more effective that the eddy current 51 and the eddy current 52 flow through the suppression unit 13. Can be prevented.

  Further, the magnitudes of the eddy current 51 and the eddy current 52 are smaller than the eddy current 50 as shown in FIG. Therefore, the magnetic field noise given to the magnetic sensor 12 by the eddy current 50 is generated as noise with respect to the main sensitivity axis 30 of the magnetic sensor 12 by replacing the magnetic field by the eddy current 51 and the eddy current 52. Can be suppressed.

  Therefore, the generation of eddy current can be suppressed by having the suppression portion 13 in the ground conductor 11 while reducing the noise due to the stray capacitance that may occur between the current path 10 and the magnetic sensor 12 by the ground conductor 11. Since the suppression portion 13 is formed in a closed region surrounded by the conductor region, it is effective without unnecessarily dividing the ground conductor 11 and unnecessarily expanding the noise generation space due to stray capacitance. In addition, the flow of eddy current can be suppressed.

  In particular, since the direction in which the suppression unit 13 extends is along the direction of the main sensitivity axis, the eddy current generated on the ground conductor 11 is prevented from crossing at a position along the main sensitivity axis 30. Therefore, it is possible to prevent a decrease in current detection accuracy caused by the eddy current 50 crossing the main sensitivity axis 30.

(Other embodiments)
In the above-described embodiment, the suppression unit 13 is provided in the direction along the main sensitivity axis 30. However, in order to further increase the current detection accuracy, an embodiment in which the shape of the suppression unit 13 is different will be described. To do.

  FIG. 8 is a side sectional view showing the positional relationship between the current path 10 and the magnetic sensor 12 according to another embodiment. 8 is basically the same as the side cross-sectional view shown in FIG. 3, but the above-described suppression unit 13 is composed of only the first suppression unit 81, but the suppression unit 13 is the first. The second suppression unit 82 is different from the main sensitivity axis 30 in that a secondary sensitivity axis 85 is shown.

  Both the first suppression unit 81 and the second suppression unit 82 are on the surface of the ground conductor 11 and are perpendicular to each other. The secondary sensitivity axis 85 faces the direction along the second suppressing portion 82. Since the GMR element is used as the magnetic sensor 12 as described above, the main sensitivity axis 30 has been described as one of the sensitivity axes of the magnetic sensor 12, but there is a secondary sensitivity axis 85 in addition to this. Then, the 2nd suppression part 82 is provided along the direction of this subsensitivity axis | shaft 85. FIG.

  That is, the magnetic sensor 12 has a secondary sensitivity axis 85 orthogonal to the main sensitivity axis 30. In addition to the 1st suppression part 81 extended in a predetermined direction, the suppression part 13 has the 2nd suppression part 82 which is a 2nd suppression part extended in the direction orthogonal to a predetermined direction, 1st The suppression part 81 and the second suppression part 82 are orthogonal to each other.

  FIG. 9 is a plan view for explaining the main sensitivity axis 30 and the secondary sensitivity axis 85. FIG. 9 is basically the same as the plan view of FIG. 4, but differs from the plan view of FIG. 4 in that a second suppression unit 82 and a sub-sensitivity axis 85 are provided. That is, the second suppression unit 82 and the secondary sensitivity axis 85 are along the same direction and are the same as the direction 40 of the current path 10. All of them are perpendicular to the direction of the main sensitivity axis 30 and the first suppressing portion 81 and are on the surface of the ground conductor 11.

FIG. 10 is a diagram for explaining the flow of the eddy current 90. FIG. 10 is basically the same as the plan view of FIG. 5, but in FIG. 10, a second suppression unit 82 and a secondary sensitivity axis 85 are provided. As a result, the difference is that an eddy current 90 is generated.
As shown in FIG. 5, when there is no suppression unit 13, eddy current 50 is generated. By providing the suppression unit 13, eddy current 51 and eddy current 52 are obtained. In the present embodiment, the flow is changed to the eddy current 90 by further providing the second suppressing portion 82.

  In this embodiment, since the second suppressing portion 82 is provided, the eddy current 51 crosses the second suppressing portion 82 as much as the ground conductor 11 is further separated at the position of the second suppressing portion 82. Flow of the eddy current 52 can be suppressed. As a result, the eddy current 90 flows through the ground conductor 11 while avoiding the position of the second suppressing portion 82.

  That is, the eddy current 90 does not cross the second suppression unit 82, and further does not cross the first suppression unit 81, and passes through the four planar regions separated by the first suppression unit 81 and the second suppression unit 82. An eddy current 90 flows so as to rotate. Each flows in the opposite direction with respect to the first suppression unit 81. Therefore, in the magnetic sensor 12 corresponding to the position of the second suppression unit 82, the effect of the magnetic field generated by the eddy current 90 is further reduced or offset with respect to the secondary sensitivity axis 90.

  FIG. 11 is a diagram illustrating a case where the second suppression unit 82 is provided. In FIG. 11, as in FIG. 7, the magnitude of the eddy current flowing on the ground conductor 11 is represented by contour lines. 7 shows the flow of the eddy current 51 and the eddy current 52 due to the provision of the suppression unit 13, while FIG. 11 describes the flow of the eddy current 90 shown in FIG. 10.

At the position 91, for example, the current density is 62.5 kA / m ² or less. At the position 92, the current density is higher than that, for example, a current density of 62.5 to 100 kA / m ² or less. At the outer position 93, the current density is higher than that, for example, a current density of 100 kA / m ² or more. As in the case of FIG. 7, although not shown by contour lines, the current density is the same as that of the position 91 near the center of the first suppression unit 81, while a large current density is present at both ends of the first suppression unit 81. Show.

  Thus, by providing the 2nd suppression part 82 in addition to the 1st suppression part 81, while the magnitude | size of the eddy current 90 falls as a whole compared with the eddy currents 51 and 52, the 1st suppression part 81, The eddy current 90 does not pass through the position of the second suppression unit 82. Such suppression of the eddy currents 51 and 52 can be realized by providing a minimum gap in the ground conductor 11.

  With the above configuration, since the second suppression portion 82 is provided in addition to the first suppression portion 81 inside the planar region of the ground conductor 11, the hole provided by the second suppression portion 82 is provided. Alternatively, the eddy current 50 does not flow across the groove. Therefore, the flow of the eddy current 50 becomes a flow like the eddy current 90 by forming a flow that avoids the first suppressing portion 81 and the second suppressing portion 82. An eddy current 90 is generated due to a temporal change in the magnitude of the current flowing through the current path 10, but the eddy current 90 does not pass through the first suppression unit 81 and the second suppression unit 82.

  Further, the magnitude of the eddy current 90 is smaller than the eddy current 50 as shown in FIG. Therefore, the noise of the magnetic field applied to the magnetic sensor 12 by the eddy current 51 and the eddy current 52 is replaced with the magnetic field due to the eddy current 90, so that the main sensitivity axis 30 of the magnetic sensor 12 and the secondary sensitivity axis 85 are Generation of noise can be suppressed.

  Therefore, the noise due to the stray capacitance that may occur between the current path 10 and the magnetic sensor 12 is reduced by the ground conductor 11, while the first suppression unit 81 along the main sensitivity axis 30 and the first along the sub sensitivity axis 80. Since two suppression portions 82 are provided, crossing of the eddy currents 50 on the magnetic sensor 12 can be suppressed. Since the suppression portion 13 is formed in a closed region surrounded by the conductor region, it is effective without unnecessarily dividing the ground conductor 11 and unnecessarily expanding the noise generation space due to stray capacitance. In addition, the flow of eddy current can be suppressed.

  The present invention is not limited to the embodiment described above. That is, those skilled in the art may make various modifications, combinations, subcombinations, and alternatives regarding the components of the above-described embodiments within the technical scope of the present invention or an equivalent scope thereof.

  Although the embodiment has been described for a vehicle device, the present invention is not particularly limited to a vehicle application, and is used for a current sensor for a current path in which a so-called relatively large current is generated. be able to.

DESCRIPTION OF SYMBOLS 1 ... Current sensor 10 ... Current path 11 ... Grounding conductor 12 ... Magnetic sensor 13 ... Control part 14 ... Substrate 15 ... Magnetic shield 21 ... Mounting part 30 ... Main sensitivity axis 50 ... Eddy current 51 ... Eddy current 52 ... Eddy current 80 ... Sub-suppression unit 81 ... first suppression unit 82 ... second suppression unit 85 ... sub-sensitivity axis 90 ... eddy current

Claims (5)

A ground conductor provided on the surface of the substrate;
A magnetic sensor provided between a current path to be measured and the ground conductor;
The magnetic sensor has a main sensitivity axis parallel to the surface of the substrate,
The ground conductor has a suppression portion formed of an elongated hole that suppresses the flow of eddy current in a closed region surrounded by a conductor region forming the ground conductor,
The direction of the main sensitivity axis of the magnetic sensor is a current sensor along the longitudinal direction of the suppressing portion. The current sensor according to claim 1, wherein the suppressing unit extends in a direction orthogonal to a current direction of the current path. The magnetic sensor has a secondary sensitivity axis orthogonal to the primary sensitivity axis;
The suppression unit includes the first suppression unit extending in the predetermined direction, and the second suppression unit extending in a direction orthogonal to the predetermined direction, and the first suppression unit and the The current sensor according to claim 1, wherein the current sensor intersects with the second suppression unit. The current sensor according to claim 1, wherein the suppressing unit is disposed so as to overlap the magnetic sensor when viewed from the normal direction of the surface of the ground conductor. The current sensor according to claim 1, wherein the suppression unit is provided at a center in the width direction of the current path.