JPWO2011090167A1 - Energization information measuring device - Google Patents

Abstract

Provided is a small and inexpensive energization information measuring apparatus capable of measuring energization information such as current and power of a circuit to be measured with high accuracy. The power measuring apparatus includes a magnetic field sensor 10 and holding portions (first case portion 20 and second case portion 30) that hold the magnetic field sensor so as to surround a primary conductor constituting an electric circuit 40 as a measurement target. And the holding portion coincides with the direction perpendicular to the line segment connecting the center of the magnetic field sensor and the center of the magnetic field sensor, and the center of the electric circuit on the electric circuit cross section. The magnetic field sensor 10 is configured to be held in the electric path so that the distance between Oc and the center Os of the magnetic field sensor 10 is constant.

Description

  The present invention relates to an energization information measuring apparatus, and more particularly to an energization information measuring apparatus that measures energization information such as current and voltage using a magnetic thin film as a sensor.

  In the energization information measuring device, a current sensor that uses a magnetic thin film as a sensor, or a power measuring device that uses a magnetic thin film as a sensor, inputs current and voltage, and directly outputs a signal corresponding to power obtained from both inputs. and so on. A conventional current sensor includes a core in which a magnetic body having a shape surrounding an outer periphery of an electric circuit is laminated, a coil wound around the core in a toroidal shape, and a shield member disposed so as to surround the entire core and the coil portion. And a housing and a signal line. In particular, in an energization information measuring device that requires highly accurate measurement, it is necessary to make the magnetic field applied to the (sensor) generated by the current constant regardless of the electric circuit shape and the wire position.

Thus, a method for detecting energization information by providing a mechanism that keeps the distance between the detected power source and the magnetic field sensor constant has been proposed.
For example, in Patent Document 1, as illustrated in a cross-sectional explanatory diagram in FIG. 23, the current sensor 101 includes a magnetic impedance element 102, a circuit unit 105 including a drive circuit, and a current value supplied to the detected electric wire D. And a calculating unit 109 to be obtained. The magneto-impedance element 102 is disposed close to the outer periphery of the energized wire D to be detected, and generates a voltage according to the strength of the magnetic field generated around the wire to be detected. The circuit unit 105 includes a drive circuit that supplies current to the magnetic impedance element 102 to drive the magnetic impedance element 102. In addition, the calculation unit 109 obtains the value of the current supplied to the detected electric wire D based on the voltage generated in the magnetic impedance element 102. The magneto-impedance element 102 is held by a casing portion 111 (111a, 111b) made of a non-magnetic material, and a shield member 113 constituting a magnetic shield for blocking a disturbance magnetic field is provided on the outer periphery of the casing portion 111. Is provided. Since the magnetic field is detected by the magnetic impedance element 102 with high sensitivity, in this apparatus, the current passed through the detected electric wire D is stably detected. Here, the housing part 111 (111a, 111b) has a holding part 112 (112a, 112b) for holding the detected electric wire D.

  Further, an energization information measuring device having a perspective view shown in FIG. 24 and a sectional view shown in FIG. 25 has been proposed. This apparatus uses a first case portion 211 having a current detection coil 110 as a magnetic field sensor and a second case portion 212 having a recess for accommodating the detected electric wire D. A core is embedded in the second case portion, and a shield member 113 is embedded outside thereof. According to this configuration, when the electric circuit is accommodated and the first case part and the second case part are fitted, the two cores close as magnetic paths, so that the magnetic field is constant regardless of the electric circuit shape and the electric wire position. It can be.

Japanese Unexamined Patent Publication No. 2000-258464

However, in this sensor, since the magnetic body (core) surrounding the electric circuit is used so that the influence of the position shift of the electric circuit passing therethrough is reduced, there is a problem that the measuring device is enlarged. There is also a problem that the manufacturing cost increases.
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a small and inexpensive energization information measuring apparatus capable of measuring energization information such as current and power of a circuit to be measured with high accuracy.

  Therefore, the energization information measuring device of the present invention includes a magnetic field sensor and a holding unit that holds the magnetic field sensor so as to have a predetermined positional relationship with respect to a primary conductor that constitutes an electric circuit as a measurement object, The holding unit is configured such that the detection direction of the magnetic field sensor coincides with a direction perpendicular to a line segment connecting the center of the electric field cross section and the center of the magnetic field sensor, and the center of the electric circuit and the magnetic field sensor on the electric circuit cross section. The magnetic field sensor is configured to be held in the electric path so that the distance from the center is constant.

  Further, the present invention is the energization information measuring device, wherein the magnetic field sensor is a sensor using a magnetoresistive effect, and is formed on the substrate so that a detection direction thereof is along the substrate plane, and the holding The portion includes a member that fixes the substrate such that the distance between the center of the electric circuit and the center of the magnetic field sensor is constant.

  Also, the present invention is the above-described energization information measuring apparatus, wherein the magnetic field sensor is connected to the primary conductor, the magnetic thin film disposed so as to be parallel to the primary conductor through which alternating current flows, and the magnetic A power supply unit including an input / output terminal for supplying an element current to the thin film through a resistor; and a detection unit including first and second power detection terminals, wherein the first and second power detections are performed. The line segment connecting the terminals includes a line segment orthogonal to the line segment connecting the input / output terminals.

  Moreover, this invention is the said electricity supply information measuring device, Comprising: The said holding | maintenance part opposes the said 1st case part which accommodates the said magnetic field sensor, and the 2nd which fixes the said electrical circuit. Including a case portion.

  Further, the present invention includes the energization information measuring device described above, wherein at least one of the first and second case portions has a recess.

  Further, the present invention is the energization information measuring device described above, wherein the magnetic field sensor is fixed in the first case part, and the second case part has an insertion hole through which the electric path is inserted, and the insertion hole Is symmetrical with respect to a line segment passing through the center of the magnetic field sensor of the first case portion and along the detection direction of the magnetic field sensor, and has a concave portion formed so as to be gradually narrowed. It includes a structure in which the primary conductors constituting the electric circuit are in contact with each other at two points on the concave cross section of the hole.

  Further, the present invention is the energization information measuring device, wherein the first conductor has a substantially circular cross section, the insertion hole opens on a surface facing the first case portion, and the first conductor The bottom surface of the concave portion located on the side farthest from one case portion includes one that forms a shape along the outer shape covering the primary conductor or the primary conductor.

  Further, the present invention is the energization information measuring apparatus described above, wherein the bottom surface is formed of a combination of arc shapes having a plurality of diameters, and the radius is smaller as the position is farther from the first case portion. including.

  Also, the present invention is the energization information measuring device, wherein the recess is longer than the length of the magnetic field sensor in the longitudinal direction of the electric path so that the electric path can be fixed on both sides of the magnetic field sensor. Includes configured ones.

  In addition, the present invention includes the energization information measuring device described above, wherein at least one of the first or second case portion includes an elastic structure that urges the electric path.

  Further, the present invention is the energization information measuring device described above, wherein the holding portion is formed on a case portion having a concave portion for accommodating the magnetic field sensor and an inner wall of the concave portion of the case portion, and holds the electric circuit. Including those composed of arm parts.

  Further, the present invention is the above-described energization information measuring device, wherein the second case part is located at a center on the cross section of the electric circuit and a center of the magnetic field sensor with respect to the first case part that houses the magnetic field sensor. It is movable along a connecting line segment, and includes a structure configured to be fixed with a primary conductor constituting the electric circuit in between.

  Further, the present invention is the energization information measuring device described above, wherein the second case portion includes an engaging portion that can be fixed to the first case portion and has elasticity, and the first case. The portion includes an engaged portion that engages with the engaging portion, and includes one in which a plurality of engaging portions or engaged portions are arranged along the line segment.

  Moreover, this invention is the said electricity supply information measuring device, Comprising: Said 2nd case part has a screw part which can be fixed to the said 1st case part in the desired position along the said line segment. Including.

  In addition, the present invention includes the energization information measurement device described above, which includes a distance determination unit that determines a distance between the electric path and the magnetic field sensor.

  In addition, the present invention includes the energization information measurement device described above, which includes a distance measurement unit that measures a relative distance between the second case unit and the first case unit.

  Moreover, this invention is said electricity supply information measuring device, Comprising: The said distance discrimination | determination part contains what is comprised with the several magnetic field sensor arrange | positioned at fixed intervals.

  Further, the present invention is the energization information measuring device described above, wherein the first and second case portions include a shield member made of a magnetic material having a U-shaped cross section, and each shield member includes the electric circuit And the magnetic field sensor are disposed so as to face each other, and the tip portion thereof is arranged so as to be shifted to avoid the facing.

  According to the present invention, the positional relationship between the electric circuit and the magnetic field sensor can be fixed, and it is possible to measure energization information such as current and voltage with high accuracy without correcting the position variation, and the size can be reduced. Cost reduction can be achieved. In particular, by taking out the DC component of the output voltage, highly accurate and reliable power measurement is possible for a power sensor that can take out power directly with a very simple configuration without separately measuring the power factor. It can be realized.

1 is a perspective view of a power measuring device according to a first embodiment of the present invention. Sectional drawing of the electric power measurement apparatus of Embodiment 1 of this invention Outline explanatory diagram of power measuring apparatus of the present invention Equivalent circuit diagram Diagram of the principle Explanatory drawing of the same power measuring device Sectional drawing of the electric power measurement apparatus of Embodiment 2 of this invention Top view of the power meter Perspective view of the power measuring device The figure which shows the same electric power measurement apparatus of Embodiment 3 of this invention. The figure which shows the same electric power measurement apparatus of Embodiment 4 of this invention. (A), (b) is a figure which shows the same electric power measuring device of Embodiment 4 of this invention. The perspective view which shows the same electric power measuring device of Embodiment 5 of this invention. The disassembled perspective view which shows the same electric power measuring device of Embodiment 5 of this invention. (A), (b) is sectional drawing which shows the same electric power measuring device of Embodiment 6 of this invention. (A), (b) is sectional drawing which shows the same electric power measuring device of Embodiment 6 of this invention. (A), (b) is sectional drawing which shows the same electric power measuring device of Embodiment 6 of this invention. The perspective view which shows the same electric power measuring device of Embodiment 7 of this invention. The perspective view which shows the same electric power measuring device of Embodiment 7 of this invention. Sectional drawing which shows the same electric power measuring device of Embodiment 8 of this invention Sectional drawing which shows the same electric power measuring device of Embodiment 9 of this invention Sectional drawing which shows the same electric power measuring device of Embodiment 10 of this invention. The figure which shows the electric power measurement apparatus of a prior art example The figure which shows the electric power measurement apparatus of a prior art example The figure which shows the electric power measurement apparatus of a prior art example

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
(Embodiment 1)
The power measuring device as the energization information measuring device according to the first embodiment of the present invention can improve the positional accuracy between the magnetic field sensor 10 and the electric circuit 40 as the measured object, and can easily obtain highly reliable measurement accuracy. It is what I did. As shown in a perspective view in FIG. 1 and a cross-sectional view in FIG. 2, the magnetic field sensor 10 and a holding unit that holds the magnetic field sensor 10 so as to surround a primary conductor that constitutes an electric circuit 40 as a measurement object. Then, by this holding unit, the magnetic field sensor 10 is placed in the electric path 40 so that the detection direction Ds of the magnetic field sensor 10 coincides with the direction perpendicular to the line segment Lo connecting the center Oc on the cross section of the electric path 40 and the center Os of the magnetic field sensor 10. Holding. The magnetic field sensor 10 is held so that the distance between the center Oc of the electric circuit 40 and the center Os of the magnetic field sensor 10 is constant on the cross section of the electric circuit 40.

  As will be described in detail below, the magnetic field sensor 10 is a sensor using a magnetoresistive effect, and a magnetic thin film and a wiring pattern formed on the substrate 11 such that the detection direction Ds is along the plane of the substrate 11. The sensor part 12 which consists of these is comprised. And this board | substrate 11 is the center Oc of the electric circuit 40, and the center of the sensor part 12 of the magnetic field sensor 10 by the holding part which consists of the 1st case part 20 and the 2nd case part 30 engaged with this. The distance to Os is fixed.

  And this holding | maintenance part is comprised by the 1st case part 20 and the 2nd case part 30 engaged with this. And the magnetic field sensor 10 is fixed in this 1st case part 20, and the 2nd case part 30 has the insertion hole 35 which penetrates the electric circuit 40, and the elastic piece 33 which protrudes from both sides to this insertion hole 35, The primary conductor which comprises the electric circuit 40 is hold | maintained. In this way, the electric path 40 is positioned on the magnetic field sensor 10 so as to be symmetric with respect to a line segment passing through the center Os of the magnetic field sensor 10 of the first case portion 20 and along the detection direction Ds of the magnetic field sensor 10. .

  The electric wire 41 as the primary conductor has a substantially circular cross section, and the insertion hole 35 formed in the second case portion 30 opens on the side facing the first case portion 20. The elastic piece 33 protruding from the second case portion 30 forms a shape along the shape of the outer skin 42 covering the electric wire 41, and elastically fixes the electric wire 41.

Further, the second case portion 30 has a groove portion 34 as an engaging portion that can be fixed to the first case portion 20 and has elasticity, and the first case portion is engaged with the groove portion 34. A combination piece 24 is provided, and a plurality of the groove portions 34 are arranged along the line segment Lo.
The second case portion 30 is formed to be smaller than the first case portion 20 and can move in the normal direction of the substrate using the inner surface of the first case portion 20 as a guide. Since a plurality of groove portions 34 are formed in parallel and engage with the tip of the engagement piece 24 formed in the first case portion 20, the positional relationship between the two can be fixed at an arbitrary groove position. It can be fixed at an optimum position with respect to electric circuits of different sizes. The engaging piece 24 is made of resin.

  Furthermore, the first and second case portions respectively have shield members 22 and 32 made of a magnetic material having a U-shaped cross section, and each of the shield members 22 and 32 includes the electric circuit and the magnetic field sensor. It arrange | positions so that it may oppose, and the front-end | tip part is shifted and arrange | positioned avoiding opposition.

As described above, in the present embodiment, the elastic piece 33 can be displaced according to the size of the electric path 40, and the volume of the insertion hole 35 can be adjusted, and the positional relationship between the electric path 40 and the magnetic field sensor 10. Can be fixed and high-precision power measurement can be performed without correcting the positional variation, so that downsizing and cost reduction can be achieved.
Further, by forming the thin film magnetic field sensor using the magnetoresistive effect on the substrate, a coil is not necessary, and it is possible to further improve the positional accuracy and to facilitate miniaturization.
Furthermore, the engagement piece 24 can be engaged with the plurality of groove portions 34, is movable along a line segment connecting the center on the cross section of the electric circuit and the center of the magnetic field sensor 10, and is configured to hold the electric circuit. Therefore, this power measuring device can be easily attached to primary conductors having different diameters.
Further, since the shield members 22 and 32 are arranged so as to avoid facing each other and are arranged in a nested manner so as to partially overlap, the shielding effect is high, and external electric wires other than the circuit to be measured in the vicinity of the magnetic field sensor The influence of the magnetic field due to the above can be suppressed.

  Next, the measurement principle of the power measuring device used in the embodiment of the present invention will be described.

In this power measurement device, paying attention to the fact that it is possible to obtain linear characteristics using the planar Hall effect, which is a phenomenon in which the electrical resistance value of the magnetic material changes depending on the angle between current and magnetization in the ferromagnetic material. The signal component proportional to is taken out. 3 and 4 show this measurement principle. FIG. 3 is a schematic explanatory diagram showing the measurement principle of the power measuring apparatus, and FIG. 4 is an equivalent circuit diagram.
The magnetic field sensor used here is an element that converts a change in an external magnetic field into an electric signal. The ferromagnetic thin film 3 as a magnetic field detection film is patterned, and a current is passed through the pattern of the magnetic field detection film to change the external magnetic field as a voltage change. Is converted into an electrical signal.
Here, as shown in FIG. 4, the ferromagnetic thin film can be regarded as a bridge circuit including resistors R1, R2, R3, and R4.

Thus, it is divided into a DC component term (first term) and an AC component term (second term).
Here, k is a coefficient determined by the film characteristic.
That is, when the resistance bridge is balanced by a zero magnetic field (R1 = R2 = R3 = R4), the output Vmr (power signal) that appears due to the applied magnetic field has a linear characteristic with respect to I ₁ and V ₂ .

This is due to the following reason.
Resistance change rate .DELTA.R1 / R1 is proportional to _{I 1,} the voltage Vb applied to the ferromagnetic thin film, capable designed proportional to _{I 2,} Vmr output is proportional to the product of _{I 1} and _{I 2.} That is, it is a signal component proportional to power. When I ₁ and I ₂ are expanded instantaneously, Vmr is (DC term) + (2ω term).

  Therefore, it is possible to extract the average power by taking out the direct current component term (DC term) which is the first term.

Next, the measurement principle of the magnetic field sensor used in the power measuring device of the present invention will be described.
In the present invention, with respect to the ferromagnetic thin film 3 used as the magnetic thin film, the output is extracted in a direction orthogonal to the element current direction and is substantially symmetric with respect to the output extraction direction.

  In other words, as shown in FIG. 5, the principle A is shown in FIG. 5 where the points A and B on the periphery of the ferromagnetic thin film pattern are symmetrical with respect to the center of the pattern of the circular ferromagnetic thin film 3, A line segment CD that is orthogonal to the line segment AB and that passes through the center of the circle is used as an output extraction direction.

At this time, as shown in FIG. 5, electric current I ₁ to the conductor disposed along the diameter direction in the ferromagnetic thin film 3, when the magnetic field generated by the current H, the spontaneous magnetization with the elements is M , The magnetic flux density vector obtained by synthesizing the magnetic field H and the spontaneous magnetization M of the element is B _M0 , the angle between the current density vector and the magnetic flux density vector is θ, and the resistance between points A and B of the ferromagnetic thin film 3 is R When the maximum resistance value between the points A and B that changes due to the magnetic field is ΔR, the voltage V _CD between the points _CD can be expressed by the difference between the voltage V _AC and the voltage V _AD .
If you formulate this,
V _CD = I ₂ (ΔR sin 2θ) (Formula 3)
Can be expressed as Here, I ₂ is a device current. This formula is explained from the planar hole effect.
That is, when an alternating magnetic field is applied, positive / negative can be determined.
In addition, there is no offset when no magnetic field is applied, and the circuit configuration can be simplified because it is zero.

By the way, when the current I ₁ is passed between the ferromagnetic thin film (between the end portions) and the detection unit (C, D) for detecting the voltage, the magnetic field generated by the current is H, and the spontaneous magnetization of the element is M. , The magnetic flux density vector obtained by synthesizing the magnetic field H and the spontaneous magnetization M of the element is B _M0 , the angle between the current density vector and the magnetic flux density vector is θ, and the resistance between points A and B of the ferromagnetic thin film 3 is R When the maximum resistance value between the points A and B that changes due to the magnetic field is ΔR, the voltage V _CD between the points _CD can be expressed by the difference between the voltage V _AC and the voltage V _AD .

  FIG. 6 shows an explanatory diagram of this power measuring device. This power measuring device includes a ferromagnetic thin film arranged parallel to a primary conductor through which alternating current flows, and an input / output that is connected to the primary conductor and supplies element current to the ferromagnetic thin film via a resistor. A magnetic field sensor 10 including a power supply unit including a terminal, a detection unit that detects outputs at both ends of the ferromagnetic thin film, and a DC component extraction unit 60 that extracts a DC component from the output of the detection unit. It is characterized by that.

Here, the power supply unit of the magnetic field sensor 10 is connected to the AC power supply 8 via a resistor 9 as a load. The DC component extraction unit 60 connected to the detection unit includes an amplifier 61, an A / D converter 62, and a CPU 63.
In addition, this power measuring device forms a magnetic field sensor 10 with a sensor unit 12 mounted on a circuit board 11 made of a printed wiring board via a wiring pattern. An amplifier 61 made of a chip component soldered to a circuit pattern on the printed wiring board, an A / D converter 62, and a CPU 63 are connected.

Here, as shown in FIG. 6, since the magnetic field sensor is formed on the circuit board 11 together with the DC component extraction unit 60, the surface S surrounded by the ferromagnetic thin film of the magnetic field sensor and the input line of the amplifier 61 is the primary conductor current. does not cross the magnetic flux generated by I _1, it is possible to reduce the influence of unwanted induced electromotive force due to flux linkage. Further, the thickness and size can be reduced.

  According to the present invention, in the power measuring apparatus, the ferromagnetic thin film is formed so that the magnetoresistance is symmetric with respect to the direction of the element current.

Since the resistance bridge is generally unbalanced, the following equation (4) is obtained. Here, it is assumed that the resistance value R1 changes to R1 + ΔR1 due to a change in magnetic resistance. The power component is the (DC) term. The unbalanced component that appears as the ω term is irrelevant to the power.

In this case, Vmr takes the maximum value when a magnetic field of θ = π / 4 is applied, but a signal can be extracted most efficiently when the configuration is symmetrical at the output extraction point. As described above, according to the above configuration, since the magnetoresistance is symmetric with respect to the direction of the element current, the maximum value of the Vmr output can be increased, and the S / N ratio as the system can be increased. improves.
Therefore, according to the above configuration, high-accuracy power measurement can be performed.

  As described above, according to the present embodiment, in the ferromagnetic body, the linear characteristic is obtained without the bias magnetic field by utilizing the planar Hall effect, which is a phenomenon in which the electric resistance value of the magnetic body changes depending on the angle between the current and the magnetization. Focusing on the points that can be obtained, high-precision power detection is realized. A signal component proportional to the electric power is extracted by the detection unit, and a DC component is extracted from the output of the detection unit by the DC component extraction unit. At this time, as described above, the electric circuit is fixed to the sensor unit with high accuracy and the magnetic resistance is arranged in the direction of the element current, so that the extracted waveform is current × voltage × force. It is a rate component, that is, electric power. For this reason, it can measure directly, without multiplying from a waveform.

(Embodiment 2)
Next, a second embodiment of the present invention will be described.
In the first embodiment, the electric path 40 is elastically held by the elastic piece 33, but the present embodiment is characterized in that a block 36 in which a concave portion 37a is formed is mounted instead of the protruding piece. FIG. 7 is a cross-sectional view of the power measuring apparatus according to the second embodiment, FIG. 8 is a top view, and FIG. 9A is a perspective view. In the present embodiment, a cross section formed so as to be symmetric with respect to a line segment passing through the center Os of the magnetic field sensor 10 of the first case portion 20 and along the detection direction Ds of the magnetic field sensor 10 and gradually becoming narrower. A block having an arcuate recess 37a is mounted. And it is comprised so that the primary conductor which comprises the electric circuit 40 may contact | connect two points of the recessed part 37a cross section of the insertion hole 35 of this block.

  Again, the holding part for fixing the electric circuit 40 is constituted by the first case part 20 and the second case part 30 engaged therewith. The magnetic field sensor 10 is fixed in the first case portion 20, and a block 36 is mounted on the inner wall of the second case portion 30, and this block forms an insertion hole 35 through which the electric path 40 is inserted. The insertion hole 35 is symmetrical with respect to a line segment passing through the center Os of the magnetic field sensor 10 of the first case portion 20 and along the detection direction Ds of the magnetic field sensor 10, and is a recess formed so as to be gradually narrowed. 37a, and the primary conductor constituting the electric circuit 40 is in contact with the recess 37a of the insertion hole 35.

The electric wire 41 as the primary conductor has a substantially circular cross section. The insertion hole 35 formed in the second case portion 30 opens on the side facing the first case portion 20. Further, the bottom surface of the concave portion 37 a located on the side farthest from the first case portion 20 forms a shape along the shape of the outer skin 42 that covers the electric wire 41.
As described above, the contour curve of the concave portion 37a of the block 36 provided in the second case portion 30 is formed so as to become smaller toward the back than the opening distance L1 at the entrance.
L1>L2> L3

Further, as is apparent from the top view shown in FIG. 8, the recess 37 a is longer than the length of the magnetic field sensor 10 in the longitudinal direction of the electric path 40, and is configured so that the electric path 40 can be fixed on both sides of the magnetic field sensor 10. Has been.
For this reason, also when forming the electric circuit 40 using the primary conductor which has a wrinkle and a distortion with respect to a longitudinal direction, the shape of a primary conductor can be correct | amended and it can match | combine with the center of a magnetic field sensor reliably.

  Further, due to this shape, the wide electric circuit is in contact with the block 36 of the second case portion 30 at a portion close to the entrance, and the narrow electric circuit is in contact with the block 36 of the second case portion 30 at a deep portion. become. Therefore, according to this apparatus, it is the shape which can always be stably inserted | pinched with two or more places with respect to the electric circuit of various magnitude | sizes.

In the embodiment, as shown in the perspective view of FIG. 9A, the entire inner wall of the block 36 is formed with the concave portion 37a, so that it can be stably supported.
On the other hand, as shown in a perspective view of FIG. 9B, a recess 37s may be formed only on the outer surface of the block 36 and supported. In this case, there is an effect that the adhesion becomes better.

(Embodiment 3)
Next, a third embodiment of the present invention will be described.
FIG. 10 shows a cross-sectional view of the power measuring apparatus according to the third embodiment of the present invention. In the power measurement device of the second embodiment, the block 36 having the concave portion 37a having a circular arc cross section is used. However, the power measurement device of the present embodiment has the following configuration. That is, in this power measuring device, the block having the concave portion 37 b whose section is tapered is attached to the inner wall of the second case portion 30. That is, the block having the concave portion 37b formed so as to be symmetric with respect to a line segment passing through the center Os of the magnetic field sensor 10 of the first case portion 20 and along the detection direction Ds of the magnetic field sensor 10 and gradually becoming narrower. Wearing. Accordingly, the primary conductors constituting the electric circuit 40 are in contact with each other at two points in the cross section of the recess 37b of the insertion hole 35.
Again, the holding part for fixing the electric circuit is composed of the first case part 20 and the second case part 30 engaged therewith. The magnetic field sensor 10 is fixed in the first case portion 20, and a block 36 is mounted on the inner wall of the second case portion 30, and this block forms an insertion hole 35 through which the electric path 40 is inserted. The insertion hole 35 is symmetrical with respect to a line segment passing through the center Os of the magnetic field sensor 10 of the first case portion 20 and along the detection direction Ds of the magnetic field sensor 10, and is a recess formed so as to be gradually narrowed. 37b. And the primary conductor which comprises the electric circuit 40 touches by two points of the recessed part 37b cross section of the penetration hole 35. FIG.

  The electric wire 41 as the primary conductor has a substantially circular cross section. The insertion hole 35 formed in the second case portion 30 opens to the surface facing the first case portion 20, and the bottom surface of the recess 37 b located on the farthest side from the first case portion 20. However, the shape along the shape of the outer skin | cover 42 which covers this electric wire 41 is comprised.

Thus, the curve of the concave portion 37b of the block 36 provided in the second case portion 30 is formed so as to become smaller toward the back than the opening distance L1 at the entrance.
L1>L2> L3

  With this shape, the wide electric circuit is in contact with the block 36 of the second case portion 30 at a portion close to the entrance, and the narrow electric circuit is in contact with the block 36 of the second case portion 30 at a deep portion. . In this way, the holding part constituted by the first case part 20 and the second case part 30 can always be stably sandwiched at two or more places with respect to the electric circuit of various sizes. It has a shape.

(Embodiment 4)
Next, a fourth embodiment of the present invention will be described.
In the second embodiment, the block 36 in which the concave portion 37a having a circular arc cross section is used, but in this embodiment, the bottom surface is formed of a combination of circular arc shapes having a plurality of diameters as shown in FIG. The block 36 having a concave portion 37c formed so that the radius thereof becomes smaller as it is located farther from the first case portion.
FIG. 12A is a diagram showing a locked state when the electric circuit 40 having a large diameter r1 is used, and FIG. 12B is a diagram showing a locked state when the electric circuit 40 having a small diameter r3 is used. In either case, the distance between the electric circuit and the magnetic field sensor can be reliably arranged.

  According to this configuration, the concave portion 37c forms a shape in which a small-diameter arc is arranged in order from a plurality of arcs having a large diameter from the entrance, and all are symmetrical. The magnetic field sensor can be arranged at a certain distance. According to this configuration, the distance between the electric circuit and the magnetic field sensor can be reliably arranged, but the center of the electric circuit is biased, and the smaller the diameter, the larger the distance from the magnetic field sensor 10, In this case, correction is performed by arithmetic processing as necessary. Alternatively, as will be described later with reference to FIG. 22 in Embodiment 10, measurement can be performed without depending on the actual distance by using two magnetic field sensors. Furthermore, when the electric path 40 having a small diameter is used, it is possible to securely fix the electric path 40 by providing an elastic body inside the block 36 and elastically holding the electric path 40.

(Embodiment 5)
Next, a fifth embodiment of the present invention will be described.
In the present embodiment, as shown in a perspective view in FIG. 13 and an exploded perspective view in FIG. 14, the first or second case portion is provided with an elastic structure made of foamed resin that urges the electric circuit 40. is there.
Here, the magnetic field sensor 10 is embedded in the second case portion 30. The first or second case portion has semi-cylindrical first and second elastic bodies 28, 38, and inner wall surfaces 29, 39 of the first and second elastic bodies 28, 38. The electric circuit is configured to be elastically fixed.

  Here, when the electric circuit is sandwiched, the elastic body bends in accordance with the outer shape of the electric circuit, and the electric circuit is biased to the center position by the reaction force. In this case, the center position of the electric circuit can be adjusted to the same position regardless of the size of the electric circuit.

  According to this configuration, since at least one of the first or second case portion has the elastic structure that uniformly urges from the surroundings with respect to the electric circuit, the shape of the primary conductor is corrected and the magnetic field is reliably Can be centered on the sensor.

(Embodiment 6)
Next, a sixth embodiment of the present invention will be described.
In this embodiment, as shown in the cross-sectional views of FIGS. 15A and 15B, a pair of holding arm portions is provided on the inner wall of the concave portion of the case portion 20 formed of a three-dimensional wiring board in which the magnetic field sensor 10 is embedded. 50, and the holding arm portion 50 holds the electric circuit. FIG. 15A shows a state before the electric circuit is mounted, and FIG. 15B shows a state where the electric circuit is mounted.
Before the electric circuit is inserted, the unfixed holding arm is widened larger than the electric circuit width, and when the electric circuit is mounted, the electric circuit is stored inside the case portion and the electric circuit position is fixed by the pressing force of the holding arm.
This holding arm is preferably made of an elastic body, has a part of a curved portion and has a shape that matches the shape of the electric circuit, and improves the fixing strength.

According to this configuration, the electric circuit can be fixed by the single case portion 20, an additional member is not necessary, and the number of parts can be reduced.
Further, as shown in the cross-sectional views of FIGS. 16A and 16B, the pair of holding arm portions 50 may hold the electric circuit 40 from the slanted upper side.
Furthermore, as shown in the cross-sectional views of FIGS. 17A and 17B, the electric circuit 40 may be held from above by one holding arm portion 50.

(Embodiment 7)
Next, a seventh embodiment of the present invention will be described.
In the present embodiment, as shown in the perspective views in FIGS. 18 and 19, the second case portion has a groove 20U that can move in parallel with respect to the first case portion 20, and the first case portion On the other hand, a screw portion 52 that can be fixed at a desired position along the line segment is included. Here, the second case portion is movable with respect to the first case portion 20 that accommodates the magnetic field sensor 10 along a line segment that connects the center of the cross section of the electric path 40 and the center of the magnetic field sensor 10, and constitutes the electric path 40. It is comprised so that it may be fixed on both sides of the primary conductor.

According to this configuration, since the screw portion 52 is held through and the electric circuit is held by the tip of the screw, the screw penetration length can be adjusted steplessly, and any size electric circuit can be adjusted. Secure and inexpensive fixation is possible without additional members.
In addition, it is movable along a line segment connecting the center on the cross section of the electric circuit and the center of the magnetic field sensor, and is configured to hold the electric circuit, so that it can be easily attached to primary conductors having different diameters. .

  Moreover, the two groove parts 20U of the 1st case part 20 extended in a longitudinal direction are made into the convex part of the 2nd case part 30 by translating the 2nd case part 30 with respect to the 1st case part 20. Since it engages with 30T, stable engagement is possible.

  The first and second case portions are combined and fixed at predetermined positions, and have a space through which the electric circuit penetrates between them. A screw portion 52 as a pressing member is penetrated and held in the second case portion 30 so that the electric path can be pressed directly at the tip or indirectly through a contact piece. And the electric circuit from which a magnitude | size differs by adjusting the screwing amount can be fixed to a fixed position.

(Embodiment 8)
Next, an eighth embodiment of the present invention will be described.
A cross-sectional view of the power measuring apparatus according to the eighth embodiment is shown in FIG. In this power measuring device, an LED light emitting element part 131 as a distance sensor light emitting part and a light receiving element part 132 for detecting reflected light from the electric path 40 are provided on the first surface 11A of the substrate 11, and the distance measuring part. Is configured. By this distance measuring unit, the distance between the first surface 11A of the substrate 11 and the electric circuit 40 can be detected. Other parts are formed in the same manner as the power measuring apparatus of the first embodiment, and the same parts are denoted by the same reference numerals.
According to this configuration, since the distance can be measured even when the electric circuit is not in direct contact with the first case portion 20, the distance is calculated from the position of the groove portion 34 with which the engagement piece 24 engages. Even with comparison, more accurate detection can be realized.

(Embodiment 9)
Next, a ninth embodiment of the present invention will be described.
A cross-sectional view of the power measuring apparatus according to the ninth embodiment is shown in FIG. This power measurement device is configured to receive an LED light emitting unit 131 that constitutes a distance sensor that optically measures a distance on a substrate 11 built in the first case unit 20, and reflected light from the upper wall of the second case. And a light receiving element portion 132 for detection. Further, this power measuring device constitutes a distance determination unit that determines the distance between the first case unit 20 and the second case unit 30 by measuring the distance between the substrate 11 and the second case unit 30. The distance from the magnetic field sensor to the circuit to be measured is measured. Other parts are formed in the same manner as the power measuring apparatus of the first embodiment, and the same parts are denoted by the same reference numerals.
With this configuration, the distance between the first case part 20 incorporating the magnetic field sensor and the second case part 30 facing the first case part 20 is measured, and thus, the first case part 20 is sandwiched between the first and second case parts 20 and 30. The size of the electric circuit 40 can be calculated. Accordingly, since the distance to the center of the electric circuit can be obtained from the size of the electric circuit, the output of the magnetic field sensor can be corrected and the power can be measured with high accuracy.

(Embodiment 10)
Next, an embodiment 10 of the invention will be described.
A cross-sectional view of the power measuring apparatus according to the tenth embodiment is shown in FIG. In this power measuring device, the first and second sensor portions 12A and 12B are arranged opposite to the first and second surfaces 11A and 11B of the substrate 11 built in the first case portion 20. Two magnetic field sensors are formed. With these two magnetic field sensors, measurement can be performed without depending on the distance to the electric circuit to be measured.
Here, magnetic field sensors (first and second sensor portions 12A and 12B) are formed opposite to each other on the first and second surfaces 11A and 11B of the substrate 11 built in the first case portion 20. When the magnetic field generated by the electric circuit is measured, the magnetic field sensor on the surface opposite to the electric circuit detects a weaker magnetic field than the other magnetic field sensor.
Here, the measurement current is I ₁ , the distance between the first and second surfaces 11A and 11B of the substrate 11 is d, the distance between the center of the electric wire (conductor) 41 and the second surface 11B is r, the first and first surfaces When the strength of the magnetic field measured by the two sensor units 12A and 12B is H _A and H _B ,
H _A = I ₁ / 2π (r + d)
H _B = I ₁ / 2π (r)
Can be represented.
From the above two formulas,
_{I 1 = 2πd · H A ·} H B / (H B -H A)
For this reason, it is possible to measure the magnetic field due to the current without depending on the distance to the electric path based on the outputs of both, and thus it is possible to measure the power with high accuracy.

Ｖ_ｍｒＡ，Ｖ_ｍｒＢをそれぞれ第１のセンサ部１２Ａ、第２のセンサ部１２Ｂの測定値として次式に示す値を得ることができる。This power measurement will be described in detail below.
In the first embodiment, the last line of (Expression 2) is expressed by the following expression.

As V _mrA and V _mrB are measured values of the first sensor unit 12A and the second sensor unit 12B, values shown in the following equations can be obtained.

In addition, k is a proportional constant related to the magnetic field and is inversely proportional to the distance according to Ampere's law.
k _A = k ′ / (r + d)
k _B = k ′ / (r)
And can be rewritten as follows:

As shown in FIG. 22, d is a distance between sensors, and is a known value determined by design.
In Equation 5, the unknowns are r and

の２つであり、
求めたい瞬時電力は、

Of the two,
The instantaneous power you want to find is

である。

It is.

  As described above, in Equation (5), two equations and two unknowns, the instantaneous power can be obtained similarly to the case of (Equation 2), and the instantaneous power can be obtained correctly regardless of the distance r.

  In the above embodiment, the magnetic field sensor may be one in which a magnetic thin film pattern is directly formed on a substrate such as a glass substrate, but once a chip is formed, the glass substrate or printed wiring board is used. You may make it mount. As a mounting method, there are a wire bonding method, a flip chip method, and the like. Further, by integrating the processing circuit in the chip, it becomes possible to provide a magnetic field sensor with higher accuracy and reliability.

The present invention is not limited to the above embodiment, and the magnetic thin film is formed so that the output extraction direction of the magnetic thin film is perpendicular to the element current direction and the magnetoresistance is symmetric with respect to the element current direction. If so, it is applicable. According to the power measuring device of the present invention, the sign of the direction can be determined, and the offset when no magnetic field is applied is eliminated, so that the circuit configuration can be simplified.
Moreover, although the magnetic field sensor using a ferromagnetic thin film was used in the said embodiment, you may use another magnetic field sensor, without being limited to this.

The outline of the embodiment of the present invention will be described below.
The energization information measuring device of the present invention includes a magnetic field sensor, and a holding unit that holds the magnetic field sensor so as to have a predetermined positional relationship with respect to a primary conductor constituting an electric circuit as a measurement object, The holding unit is configured so that a detection direction of the magnetic field sensor coincides with a direction perpendicular to a line segment connecting the center of the electric field section and the center of the magnetic field sensor, and the center of the electric circuit and the center of the magnetic field sensor on the electric circuit section. The magnetic field sensor is configured to be held in the electric path so that the distance to the electric path is constant.
According to this configuration, the positional relationship between the electric circuit and the magnetic field sensor can be fixed at a correct position, and high-accuracy measurement can be performed without correcting position variation, thereby reducing the size of the apparatus. At the same time, the cost can be reduced.

Further, the present invention is the energization information measuring device, wherein the magnetic field sensor is a sensor using a magnetoresistive effect, and is formed on the substrate so that a detection direction thereof is along the substrate plane, and the holding The portion includes a member that fixes the substrate such that the distance between the center of the electric circuit and the center of the magnetic field sensor is constant.
According to this configuration, the magnetic field sensor using the magnetoresistive effect is formed on the substrate, so that a coil is not necessary, the positional accuracy can be further improved, and miniaturization is facilitated.

Also, the present invention is the above-described energization information measuring apparatus, wherein the magnetic field sensor is connected to the primary conductor, the magnetic thin film disposed so as to be parallel to the primary conductor through which alternating current flows, and the magnetic A power supply unit including an input / output terminal for supplying an element current to the thin film through a resistor; and a detection unit including first and second power detection terminals, wherein the first and second power detections are performed. The line segment connecting the terminals includes a line segment orthogonal to the line segment connecting the input / output terminals.
According to this configuration, it is possible to maintain the positional relationship between the detection direction and the primary conductor that is the object to be measured with high accuracy.

Moreover, this invention is the said electricity supply information measuring device, Comprising: The said holding | maintenance part opposes the said 1st case part which accommodates the said magnetic field sensor, and the 2nd which fixes the said electrical circuit. Including a case portion.
According to this configuration, the positions of the magnetic field sensor and the electric circuit can be fixed more reliably.

Further, the present invention includes the energization information measuring device described above, wherein at least one of the first and second case portions has a recess.
According to this configuration, by setting the electric circuit in the recess, the electric circuit can be more reliably fixed at a fixed position with respect to the magnetic field sensor.

Further, the present invention is the energization information measuring device described above, wherein the magnetic field sensor is fixed in the first case part, and the second case part has an insertion hole through which the electric path is inserted, and the insertion hole Is symmetrical with respect to a line segment passing through the center of the magnetic field sensor of the first case portion and along the detection direction of the magnetic field sensor, and has a concave portion formed so as to be gradually narrowed. It includes a structure in which the primary conductors constituting the electric circuit are in contact with each other at two points on the concave cross section of the hole.
According to this configuration, the position of the electric circuit can be stably fixed without depending on the size of the primary conductor by locking the electric circuit at a position in the recess according to the size of the primary conductor constituting the electric circuit. It becomes possible.

Further, the present invention is the energization information measuring device, wherein the first conductor has a substantially circular cross section, the insertion hole opens on a surface facing the first case portion, and the first conductor The bottom surface of the concave portion located on the side farthest from one case portion includes one that forms a shape along the outer shape covering the primary conductor or the primary conductor.
According to this configuration, since alignment can be performed along the outer skin shape, more reliable alignment is possible.

Further, the present invention is the energization information measuring apparatus described above, wherein the bottom surface is formed of a combination of arc shapes having a plurality of diameters, and the radius is smaller as the position is farther from the first case portion. including.
According to this structure, since the recessed part of the shape which combined the some circular arc from which a diameter differs is comprised, an electric circuit can be hold | maintained more reliably and stably.

Also, the present invention is the energization information measuring device, wherein the recess is longer than the length of the magnetic field sensor in the longitudinal direction of the electric path so that the electric path can be fixed on both sides of the magnetic field sensor. Includes configured ones.
According to this configuration, even when a primary conductor having a wrinkle and distortion in the longitudinal direction is used, the shape of the primary conductor can be corrected and reliably aligned with the center of the magnetic field sensor.

In addition, the present invention includes the energization information measuring device described above, wherein at least one of the first or second case portion includes an elastic structure that urges the electric path.
According to this configuration, since at least one of the first or second case portion has the elastic structure that uniformly urges from the surroundings with respect to the electric circuit, the shape of the primary conductor is corrected and the magnetic field is reliably Can be centered on the sensor.

Further, the present invention is the energization information measuring device described above, wherein the holding portion is formed on a case portion having a concave portion for accommodating the magnetic field sensor and an inner wall of the concave portion of the case portion, and holds the electric circuit. Including those composed of arm parts.
According to this configuration, the electric circuit can be fixed by a single case portion, an additional member is not required, and the number of parts can be reduced.

Further, the present invention is the above-described energization information measuring device, wherein the second case part is located at a center on the cross section of the electric circuit and a center of the magnetic field sensor with respect to the first case part that houses the magnetic field sensor. It is movable along a connecting line segment, and includes a structure configured to be fixed with a primary conductor constituting the electric circuit in between.
According to this configuration, it is movable along a line segment connecting the center on the cross section of the electric circuit and the center of the magnetic field sensor, and is configured to hold the electric circuit, so that it can be attached to a primary conductor having a different diameter. Is easy.

Further, the present invention is the energization information measuring device described above, wherein the second case portion includes an engaging portion that can be fixed to the first case portion and has elasticity, and the first case. The portion includes an engaged portion that engages with the engaging portion, and includes one in which a plurality of engaging portions or engaged portions are arranged along the line segment.
According to this configuration, it can be easily fixed to a primary conductor of any size without an additional member.

Moreover, this invention is the said electricity supply information measuring device, Comprising: Said 2nd case part has a screw part which can be fixed to the said 1st case part in the desired position along the said line segment. Including.
According to this configuration, since the screw is held through and the electric circuit is held by the tip of the screw, it is possible to adjust the screw penetration length steplessly, and an additional member for any size electric circuit It is possible to fix securely and inexpensively.

In addition, the present invention includes the energization information measurement device described above, which includes a distance determination unit that determines a distance between the electric path and the magnetic field sensor.
According to this configuration, it is possible to detect the size of the electric circuit from the output of the distance determination unit, and it is possible to easily measure without setting the electric circuit size in advance for the sensor.

In addition, the present invention includes the energization information measurement device described above, which includes a distance measurement unit that measures a relative distance between the second case unit and the first case unit.
According to this configuration, the size of the electric circuit can be detected from the output of the distance measuring unit, and the measurement can be easily performed without setting the size of the electric circuit for the sensor.

Moreover, this invention is said electricity supply information measuring device, Comprising: The said distance discrimination | determination part contains what is comprised with the several magnetic field sensor arrange | positioned at fixed intervals.
According to this configuration, it is possible to measure the relative distance between the second case portion and the first case portion with a magnetic field sensor without providing a separate distance determining portion.

Further, the present invention is the energization information measuring device described above, wherein the first and second case portions include a shield member made of a magnetic material having a U-shaped cross section, and each shield member includes the electric circuit And the magnetic field sensor are disposed so as to face each other, and the tip portion thereof is arranged so as to be shifted to avoid the facing.
According to this configuration, it is possible to suppress the influence of a magnetic field due to an external electric wire or the like other than the electric circuit to be measured in the vicinity of the magnetic field sensor.

  As described above, according to the energization information measuring device of the present invention, correct power measurement can be performed even when the power factor is not 1 or even a load including a harmonic current. Therefore, since it is possible to reduce the size and cost as compared with a conventional power measuring device using a current sensor such as a current transformer, it can be applied to various energy saving tools.

  This application is based on a Japanese patent application (Japanese Patent Application No. 2010-011460) filed on Jan. 21, 2010, the contents of which are incorporated herein by reference.

3 Ferromagnetic thin film ((annular) pattern)
A and B points (feeding part)
C, D points (detector)
DESCRIPTION OF SYMBOLS 10 Magnetic field sensor 11 Circuit board 11A 1st surface 11B 2nd surface 12 Sensor part (magnetic thin film)
12A 1st sensor part 12B 2nd sensor part 20 1st case part 22 Shield member 24 Engagement piece 30 2nd case part 32 Shield member 33 Elastic piece 34 Groove part 35 Insertion hole 40 Electric path 41 Electric wire 42 Outer skin

Claims (18)

A magnetic field sensor;
A holding unit for holding the magnetic field sensor so as to have a predetermined positional relationship with respect to a primary conductor constituting an electric circuit as a measurement object;
Have
The holding part is
The detection direction of the magnetic field sensor coincides with the direction perpendicular to the line segment connecting the center on the electric circuit cross section and the center of the magnetic field sensor,
An energization information measuring device configured to hold the magnetic field sensor in the electric circuit so that a distance between the center of the electric circuit and the center of the magnetic field sensor is constant on the cross section of the electric circuit. The energization information measuring device according to claim 1,
The magnetic field sensor is a sensor using a magnetoresistive effect,
The detection direction is formed on the substrate so as to be along the substrate plane,
The energization information measuring device, wherein the holding unit fixes the substrate so that the substrate has a constant distance between the center of the electric circuit and the center of the magnetic field sensor. The energization information measuring device according to claim 1 or 2,
A magnetic thin film arranged such that the magnetic field sensor is parallel to the primary conductor through which alternating current flows;
A power feeding unit including an input / output terminal connected to the primary conductor and supplying an element current to the magnetic thin film via a resistor;
A detection unit including first and second power detection terminals for detecting the output of the magnetic thin film;
An energization information measuring device in which a line segment connecting the first and second power detection terminals is orthogonal to a line segment connecting the input / output terminals. The energization information measuring device according to any one of claims 1 to 3,
The holding part is
A first case for housing the magnetic field sensor;
An energization information measuring device having a second case portion facing the first case portion and fixing the electric circuit. The energization information measuring device according to claim 4,
An energization information measuring device in which at least one of the first and second case portions has a recess. The energization information measuring device according to claim 5,
The magnetic field sensor is fixed in the first case portion,
The second case portion has an insertion hole through which the electric path is inserted,
The insertion hole is symmetric with respect to a line segment passing through the center of the magnetic field sensor of the first case portion and along the detection direction of the magnetic field sensor,
An energization information measuring device having a recess formed so as to be gradually narrowed, and configured so that a primary conductor constituting the electric circuit is in contact with two points of a cross section of the recess of the insertion hole. The energization information measuring device according to claim 6,
The first conductor has a substantially circular cross section;
The insertion hole opens on the side facing the first case portion,
An energization information measuring device in which a bottom surface of the concave portion located on the side farthest from the first case portion forms a shape along the outer shape covering the primary conductor or the primary conductor. The energization information measuring device according to claim 7,
The energization information measuring device, wherein the bottom surface is composed of a combination of arc shapes having a plurality of diameters, and the radius is smaller as the distance from the first case portion is more distant. The energization information measuring device according to claim 8,
The energization information measuring device is configured such that the concave portion is longer than the length of the magnetic field sensor in the longitudinal direction of the electric circuit, and the electric circuit can be fixed on both sides of the magnetic field sensor. The energization information measuring device according to any one of claims 1 to 4,
An energization information measuring device comprising an elastic structure in which at least one of the first or second case portion biases the electric circuit. The energization information measuring device according to any one of claims 1 to 3,
The holding part is
A case portion having a recess for accommodating the magnetic field sensor;
An energization information measuring device formed of a holding arm portion that is formed on the inner wall of the concave portion of the case portion and holds the electric circuit. The energization information measuring device according to any one of claims 4 to 9,
The second case portion is in contrast to the first case portion that houses the magnetic field sensor.
It is movable along a line segment connecting the center on the cross section of the electric circuit and the center of the magnetic field sensor,
An energization information measuring device configured to sandwich and fix a primary conductor constituting the electric circuit. The energization information measuring device according to claim 11,
The second case portion includes an engaging portion that can be fixed to the first case portion and has elasticity, and the first case portion includes an engaged portion that engages with the engaging portion. An energization information measuring device having a plurality of engaging portions or engaged portions arranged along the line segment. The energization information measuring device according to claim 11,
The energization information measuring device, wherein the second case part has a screw part that can be fixed to the first case part at a desired position along the line segment. The energization information measuring device according to claim 12 or 14,
An energization information measuring device comprising a distance discriminating unit that discriminates a distance between the electric path and the magnetic field sensor. The energization information measuring device according to claim 12 or 14,
An energization information measuring device including a distance measuring unit that measures a relative distance between the second case unit and the first case unit. The energization information measuring device according to claim 15,
The distance discriminating unit is an energization information measuring device including a plurality of magnetic field sensors arranged at regular intervals. The energization information measuring device according to any one of claims 1 to 17,
The first and second case portions have shield members made of a magnetic material having a U-shaped cross section,
The shield members are arranged to face each other so as to cover the electric circuit and the magnetic field sensor,
An energization information measuring device in which the tip portion is arranged so as to avoid being opposed to each other.

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