JP2014020939A - Magnetic ore piece and current measuring system using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a magnetic ore piece and a current measuring system using the magnetic ore piece which achieve a wide measuring range and high measurement accuracy.SOLUTION: A magnetic ore piece which is inserted into the inside of a magnetization coil includes a first magnetic body and a second magnetic body. The second magnetic body is installed in alignment with the first magnetic body in an axial direction of the magnetization coil inside the magnetization coil, and is magnetized at the same time as the first magnetic body by a magnetic field generated when current flows in the magnetization coil. Both of the first and second magnetic bodies differ from each other in relation between magnetic flux density and magnetic field intensity.

Description

  Embodiments described herein relate generally to a magnetic steel strip and a current measurement system using the same.

  In the current measuring system, when a current flows through the magnetizing coil while being inserted into the magnetizing coil, the magnetic steel strip is magnetized by a magnetic field generated by the current. Thereafter, the value of the current flowing through the magnetizing coil is measured by measuring the residual magnetism retained by the magnetic steel piece and obtaining the value of the magnetization current of the magnetic steel piece.

  For example, in a current measurement system, in order to measure a discharge current discharged from a lightning arrester during a lightning strike, a magnetizing coil is electrically connected to the ground terminal of the arrester, and a magnetic steel piece is installed inside the magnetizing coil ( For example, see Patent Document 1).

JP-A-9-89942 (see paragraphs 0007, 0008, etc.)

  However, in the above current measurement system, since the BH characteristic of the magnetic steel piece is single, the current measurable range is narrow, and it may be difficult to obtain sufficient measurement accuracy.

  Specifically, the value of the lightning strike current covers a wide range from several kA to several hundred kA. For example, when saturation magnetization occurs in a magnetic steel piece at a small current, the current in which the saturation magnetization occurs Cannot be measured for higher currents. For example, when a magnetic steel piece capable of measuring a relatively large current is used, the measurement accuracy is reduced for a small current of about several tens of A.

  Therefore, the problem to be solved by the present invention is to provide a magnetic steel strip and a current measurement system having a wide measurement range and high measurement accuracy.

  The magnetic steel piece of the embodiment is a magnetic steel piece inserted into the magnetization coil, and has a first magnetic body and a second magnetic body. The second magnetic body is installed alongside the first magnetic body in the axial direction of the magnetization coil inside the magnetization coil, and is magnetized simultaneously with the first magnetic body by a magnetic field generated when a current flows through the magnetization coil. The first magnetic body and the second magnetic body are different from each other in the relationship between the magnetic flux density and the magnetic field strength.

FIG. 1 is a diagram illustrating components of the current measurement system according to the first embodiment. FIG. 2 is a diagram illustrating components of the current measurement system according to the first embodiment. FIG. 3 is a diagram illustrating components of the current measurement system according to the first embodiment. FIG. 4 is a diagram illustrating components of the current measurement system according to the first embodiment. Drawing 5 is a sectional view showing each of the 1st magnetic steel piece part and the 2nd magnetic steel piece part which constitute a magnetic steel piece in the current measurement system concerning a 1st embodiment. FIG. 6 is a side view showing a state in which the magnetized portion is installed in the current measurement system according to the first embodiment. FIG. 7 is a diagram showing the relationship between the magnetizing current and the remanent magnetism in the current measurement system according to the first embodiment. FIG. 8 is a diagram showing a magnetic steel piece in the current measurement system according to the second embodiment. FIG. 9 is a diagram showing a magnetic steel piece in the current measurement system according to the second embodiment.

  Embodiments will be described with reference to the drawings.

<First Embodiment>
[A] Configuration FIGS. 1 to 4 are diagrams showing components of the current measurement system according to the first embodiment.

  1 to 4, (a) is a top view and (b) is a side view.

  As shown in each of FIGS. 1 to 4, the current measurement system includes a magnetizing unit 1, a magnetic steel piece 2, a current measuring unit 3, and a demagnetizing unit 4, and measures the polarity of the current together with the current value. To do. Details of each part constituting the current measurement system will be sequentially described below.

[A-1] Magnetized portion 1 As shown in FIGS. 1A and 1B, the magnetized portion 1 includes a support portion 11, first and second support insulators 12A and 12B, and a first portion. And the second connection terminals 13A and 13B and the magnetizing coil 14, and magnetize the magnetic steel piece 2. The magnetizing unit 1 functions as a current recorder in the current measurement system.

  Of the magnetized portion 1, the support portion 11 is a rectangular plate-like body, and a pair of through holes 11H are formed. The pair of through holes 11 </ b> H are formed in the vicinity of a pair of corners arranged in one diagonal direction on the upper surface of the support portion 11.

  Of the magnetized portion 1, the first and second support insulators 12 </ b> A and 12 </ b> B have a cylindrical shape and are installed on the upper surface of the support portion 11. Each of the first support insulator 12A and the second support insulator 12B is installed on the upper surface of the support portion 11 in the vicinity of a pair of corners arranged in another diagonal direction intersecting one diagonal direction. The first and second support insulators 12A and 12B are formed of an insulating material, and electrically insulate the support portion 11 from the first and second connection terminals 13A and 13B.

  In the magnetized portion 1, the first and second connection terminals 13A and 13B are installed on the upper surfaces of the first and second support insulators 12A and 12B, respectively.

  Specifically, the first connection terminal 13A includes a first conductive plate 131A and a first fixing plate 132A, and one end of the first conductive plate 131A is fixed to the upper surface of the first support insulator 12A, so A first fixed plate 132A is installed on the upper surface of the first conductive plate 131A at the other end of the plate 131A. The first fixed plate 132A is detachable from the first conductive plate 131A, and is attached to the first conductive plate 131A using fastening members such as bolts and nuts.

  On the other hand, the second connection terminal includes a second conductive plate 131B and a second fixed plate 132B, and one end of the second conductive plate 131B is fixed to the upper surface of the second support insulator 12B, and the second conductive plate 131B At the other end, the second fixed plate 132B is installed on the upper surface of the second conductive plate 131B. The second fixing plate 132B is detachable from the second conductive plate 131B, and is attached to the second conductive plate 131B using a fastening member such as a bolt and a nut.

  In the magnetized portion 1, the magnetizing coil 14 is formed by winding a metal plate spirally, for example, once. One end of the magnetizing coil 14 is attached to the first connection terminal 13 </ b> A using a fastening member such as a bolt, and is electrically connected. Similarly, the other end is attached using a fastening member such as a bolt and is electrically connected to the second connection terminal 13B. The magnetizing coil 14 is provided with a convex portion 141 on a portion on the second connection terminal 13B side in an inner peripheral surface of a portion wound spirally between both end portions. The convex portion 141 protrudes inward from the inner peripheral surface of the magnetizing coil 14.

[A-2] Magnetic Steel Piece 2 As shown in FIG. 2, the magnetic steel piece 2 has a first magnetic steel piece portion 21 and a second magnetic steel piece portion 22 and is magnetized in the magnetized portion 1. The The magnetic steel piece 2 functions as a current recording medium in the current measurement system.

  In the magnetic steel piece 2, both the first magnetic steel piece portion 21 and the second magnetic steel piece portion 22 are cylindrical bodies and are connected to each other.

  Then, as shown in FIG. 2A, in the first magnetic steel piece portion 21, the surface (upper surface) of the other end portion located on the opposite side to the one end portion to which the second magnetic steel piece portion 22 is connected. A mark 21M is formed on the surface. The mark 21M has, for example, a circular shape and is formed in a color different from that of the other surface portion of the magnetic steel piece 2.

  Drawing 5 is a sectional view showing each of the 1st magnetic steel piece part and the 2nd magnetic steel piece part which constitute a magnetic steel piece in the current measurement system concerning a 1st embodiment.

  In FIG. 5, (a) shows the first magnetic steel piece part 21, and (b) shows the second magnetic steel piece part 22. Both the first magnetic steel piece portion 21 and the second magnetic steel piece portion 22 are detachable from each other. In FIG. 5, unlike FIG. 2, the first magnetic steel piece portion 21 and the second magnetic steel piece portion 22. And both show a state of being separated from each other.

  As shown in FIG. 5A, the first magnetic steel piece portion 21 includes a first magnetic body 211, a first magnetic shield 212, a first insulator 213, and a female screw portion 214. In the first magnetic steel piece portion 21, the first magnetic body 211 is provided inside the first insulator 213. The first magnetic shield 212 is provided alongside the first magnetic body 211 inside the first insulator 213, and the second magnetic steel is higher than the first magnetic body 211 in the first magnetic steel piece portion 21. It is located on the side (lower side) of the end where the piece 22 is attached and detached. The female thread portion 214 is provided on the end surface (lower surface) of the first magnetic steel piece portion 21 where the second magnetic steel piece portion 22 is attached and detached, and spirally formed on the inner peripheral surface of the cylindrical recess. Grooves are formed.

  As shown in FIG. 5B, the second magnetic steel piece portion 22 includes a second magnetic body 221, a second magnetic shield 222, a second insulator 223, and a male screw portion 224. In the second magnetic steel piece portion 22, the second magnetic body 221 is provided inside the second insulator 223. The second magnetic shield 222 is provided alongside the second magnetic body 221 inside the second insulator 213, and the first magnetic steel piece portion 21 is attached to and detached from the second magnetic steel piece portion 21. It is located on the end side (upper side). The male screw portion 224 is provided on the surface (upper surface) of the end portion of the second magnetic steel piece portion 22 where the first magnetic steel piece portion 21 is attached and detached, and spirally formed on the outer peripheral surface of the cylindrical convex portion. Grooves are formed.

  The first magnetic steel piece portion 21 and the second magnetic steel piece portion 22 are connected by screwing the male screw portion 224 into the female screw portion 214.

  Among the magnetic steel pieces 2, both the first magnetic body 211 and the second magnetic body 221 are, for example, a laminated body in which silicon steel plates (not shown) and insulating plates (not shown) are alternately stacked a plurality of times. is there.

In the present embodiment, both the first magnetic body 211 and the second magnetic body 221 have different relationships (BH characteristics) between the magnetic flux density (B) and the magnetic field strength (H). The first magnetic body 211 and the second magnetic body 221 have different magnetic permeability, for example, in order to make the BH characteristics different from each other. For example, the following silicon steel plate is used so that the first magnetic body 211 has higher magnetic permeability than the second magnetic body 221. Each of the first magnetic body 211 and the second magnetic body 221 includes, for example, an insulating plate made of the following material interposed between a plurality of silicon steel plates.
-Silicon steel plate constituting the first magnetic body 211: Directional silicon steel plate (maximum magnetic permeability: 40000)
-Silicon steel plate constituting the second magnetic body 221: non-oriented silicon steel plate (maximum magnetic permeability: 10000)
-Material of the insulating plate constituting the first magnetic body 211 and the second magnetic body 221: phenol resin

Among the magnetic steel pieces 2, both the first magnetic shield 212 and the second magnetic shield 222 are magnetic bodies having a larger permeability than the first magnetic body 211 and the second magnetic body 221. For this reason, the following materials are used for each of the first magnetic shield 212 and the second magnetic shield 222, for example.
-Material of the first magnetic shield 212 and the second magnetic shield 222: Permalloy (maximum magnetic permeability: 120000)

Among the magnetic steel pieces 2, both the first insulator 213 and the second insulator 223 are formed using, for example, the following materials.
-Material of the first insulator 213 and the second insulator 223: for example, a resin such as a two-component mixed urethane resin or epoxy resin

  In the magnetic steel piece 2, the first magnetic steel piece portion 21 is formed by, for example, molding an insulating material around the first magnetic body 211 and the first magnetic shield 212, and forming the female screw portion 214 on the first insulator 213. Manufactured by doing. Similarly, the second magnetic steel piece portion 22 is formed by, for example, molding an insulating material around the second magnetic body 221 and the second magnetic shield 222 and forming a male screw portion 224 on the second insulator 223. Manufactured.

  Although details will be described later, the magnetic steel piece 2 is inserted into the magnetization coil 14 of the magnetized portion 1, and the first magnetic body 211 and the second magnetism constituting the magnetic steel piece 2 inside the magnetization coil 14. Both the body 221 and the body 221 are magnetized simultaneously.

[A-3] About Current Measurement Unit 3 As shown in FIG. 3, the current measurement unit 3 includes a current measurement unit main body 31 and a compass magnetometer 32 and measures the magnetization current of the magnetic steel piece 2.

  In the current measuring unit 3, the current measuring unit main body 31 is a rectangular parallelepiped, and an insertion port 31H is formed on a side surface. The insertion port 31H has a cylindrical shape and the central axis is along the horizontal direction. In addition, a mark 31M is provided around the side surface of the current measurement unit main body 31 where the insertion port 31H is provided. The mark 31M has a ring shape and is formed in the same color as the mark 21M (see FIG. 2A) provided on the magnetic steel piece 2.

  In the current measuring unit 3, the compass magnet 32 is installed on the upper surface of the current measuring unit main body 31. The compass needle meter 32 includes a magnetic needle 321 and a scale plate 322. The magnetic needle 321 is supported at the center of the circular scale plate 322, and rotates around the center of the scale plate 322 as a rotation axis according to the surrounding magnetism. Although not shown, the scale plate 322 displays an angle as a scale in the rotation direction of the magnetic needle 321 along with the orientation.

[A-4] About the demagnetization part 4 As shown in FIG. 4, the demagnetization part 4 has the demagnetization part main body 41 and the demagnetization coil part 42, and erases the residual magnetism of the magnetic steel piece 2. As shown in FIG.

  In the demagnetizing unit 4, the demagnetizing unit main body 41 is a plate-like body, and a pair of power supply terminals 411 and a power switch 412 are provided on the upper surface next to the demagnetizing coil unit 42.

  In the demagnetizing section 4, the demagnetizing coil section 42 includes a support section 421 and an insertion tube 422, the support section 421 is installed on the upper surface of the demagnetization section main body 41, and the insertion tube 422 penetrates the side portion of the support section 421. ing. As shown by a broken line in FIG. 4, the degaussing coil portion 42 is provided with a degaussing coil 421 </ b> C around the insertion tube 422 inside the support portion 421.

[B] Operation Hereinafter, a method for measuring current using the current measurement system will be described.

[B-1] Installation of Magnetized Part 1 First, the magnetized part 1 (see FIG. 1) is installed in a current path through which a current to be measured flows.

  FIG. 6 is a side view showing a state in which the magnetized portion is installed in the current measurement system according to the first embodiment.

  As shown in FIG. 6, when the discharge current discharged from the lightning arrester 5 is measured, the magnetized portion 1 is installed in the current path between the ground terminal 51 of the lightning arrester 5 and the ground.

  As shown in FIG. 6, the lightning arrester 5 is installed on the upper surface of the support base 6, and the discharge counter 7 is installed on the side surface of the support base 6 via a support insulator 71. Here, the ground terminal 51 of the lightning arrester 5 and one terminal 72 </ b> A of the discharge counting unit 7 are electrically connected via a conductor 81.

  And the magnetizing part 1 is installed through the support insulator 15 in the position below the position in which the discharge counting part 7 was installed among the side surfaces of the support stand 6. Here, the first connecting terminal 13 </ b> A of the magnetizing unit 1 and the other terminal 72 </ b> B of the discharge counting unit 7 are electrically connected by the conductor 82. Then, the conductor 83 is electrically connected between the second connection terminal 13 </ b> B of the magnetized portion 1 and the ground.

  More specifically, when the magnetized portion 1 is installed on the support insulator 15 provided on the side surface of the support base 6, as shown in FIG. 1, a pair of magnets 1 formed on the support portion 11 of the magnetized portion 1. A fastening member (not shown) such as a bolt is passed through the through hole 11H, and the magnetized portion 1 is attached to the support insulator 15. When the first connection terminal 13A and the conductor 82 are connected, the conductor 82 (see FIG. 6) is inserted between the first conductive plate 131A and the first fixing plate 132A, and then the first conductive plate 131A and the conductor 82 are connected. The first fixing plate 132A is fastened with a fastening member. Similarly, when connecting the second connection terminal 13B and the conductor 83, after inserting the conductor 83 (see FIG. 6) between the second conductive plate 131B and the second fixing plate 132B, the second conductive plate A fastening member fastens between 131B and the second fixing plate 132B.

[B-2] Installation of Magnetic Steel Piece 2 Next, the magnetic steel piece 2 (see FIG. 2) is installed inside the magnetizing coil 14 of the magnetized portion 1.

  Here, as shown in FIG. 6, the magnetic steel piece 2 in which the first magnetic steel piece portion 21 and the second magnetic steel piece portion 22 are connected to each other is inserted into the magnetizing coil 14. At this time, the magnetic steel piece 2 is installed in the magnetizing coil 14 so that the first magnetic steel piece portion 21 is located above and the second magnetic steel piece portion 22 is located below. That is, as shown in FIG. 2, the upper surface of the magnetic steel piece 2 on which the mark 21M is formed is directed upward. Thereby, as shown in FIG. 5, both the 1st magnetic body 211 and the 2nd magnetic body 221 which comprise the magnetic steel piece 2 are installed along with the axial direction (winding-axis direction) of the magnetization coil 14. As shown in FIG. Inside the magnetizing coil 14, the magnetic steel piece 2 is supported by a convex portion 141 (see FIG. 1) provided on the inner peripheral surface of the magnetizing coil 14.

[B-3] Magnetization of Magnetic Steel Piece 2 When a current flows through the magnetization coil 14 in a state where the magnetic steel piece 2 is installed inside the magnetization coil 14, the magnetic steel piece 2 is magnetized.

  Specifically, as shown in FIG. 6, when a discharge current flows from the lightning arrester 5 through the magnetization coil 14 through the discharge counter 7 due to a lightning strike, a magnetic field is generated inside the magnetization coil 14, and the generated magnetic field is generated. Thus, the magnetic steel piece 2 is excited.

  In the present embodiment, as shown in FIG. 5, both the first magnetic body 211 and the second magnetic body 221 are magnetized simultaneously in the magnetic steel piece 2. At this time, each of the first magnetic body 211 and the second magnetic body 221 is magnetized according to the BH characteristic, and retains residual magnetism having different values after magnetization.

  Further, as shown in FIG. 5, in the magnetic steel piece 2, magnetism is shielded between the first magnetic body 211 and the second magnetic body 221 by the first magnetic shield 212 and the second magnetic shield 222. The For this reason, the residual magnetism of the first magnetic body 211 and the residual magnetism of the second magnetic body 221 are not interfered with each other.

[B-4] Measurement of Current Next, the magnetization current of the magnetic steel piece 2 is measured.

  Here, first, the magnetic steel piece 2 is taken out from the inside of the magnetizing coil 14. Thereafter, the first magnetic steel piece portion 21 and the second magnetic steel piece portion 22 connected in the magnetic steel piece 2 are separated as shown in FIG. And each magnetizing current of the 1st magnetic steel piece part 21 and the 2nd magnetic steel piece part 22 is calculated | required using the current measurement part 3 (refer FIG. 3).

  When obtaining the magnetizing current, the orientation of the magnetic needle 321 is set to the reference position of the scale plate 322 in the azimuth magnetic needle meter 32 of the current measuring unit 3 as shown in FIG. That is, the north pole of the magnetic needle 321 is set to the 0 ° position indicated on the scale plate 322.

  And as shown in FIG. 3, the 1st magnetic steel piece part 21 (refer FIG. 2, FIG. 5) is inserted in the insertion port 31H provided in the electric current measurement part main body 31 in the electric current measurement part 3. As shown in FIG. When the first magnetic steel piece portion 21 is inserted, a mark 31M (see FIG. 3B) of the current measuring portion main body 31 and a mark 21M provided on the upper surface of the first magnetic steel piece portion 21 (FIG. 2). Both are aligned so that both are oriented in the same direction. Thereby, the polarity of magnetization can be grasped.

  When the first magnetic steel piece portion 21 is inserted into the insertion port 31H of the current measuring portion main body 31, depending on the residual magnetism of the first magnetic body 211 (see FIG. 5) provided inside the first magnetic steel piece portion 21. As a result, the magnetic needle 321 of the azimuth meter 32 rotates and moves from the reference position. At this time, the magnitude of the angle at which the magnetic needle 321 swings from the reference position and the direction of the swing are read. Then, the value and polarity of the magnetizing current of the first magnetic steel piece portion 21 are obtained from the magnitude of the angle at which the magnetic needle 321 swings from the reference position and the direction of the swing. For example, the value of the magnetic current corresponding to the magnitude of the angle measured this time is obtained using data measured in advance regarding the relationship between the magnitude of the angle at which the magnetic needle 321 has swung from the reference position and the value of the magnetic current.

  After obtaining the magnetization current for the first magnetic steel piece portion 21 (see FIGS. 2 and 5), the magnetization current of the second magnetic steel piece portion 22 is obtained in the same manner.

  That is, the direction of the magnetic needle 321 is adjusted to the reference position of the scale plate 322 in the azimuth magnetic needle meter 32 of the current measuring unit 3 (see FIG. 3). Then, the 2nd magnetic steel piece part 22 (refer FIG. 2, FIG. 5) is inserted in the insertion port 31H of the electric current measurement part main body 31. FIG. When the second magnetic steel piece portion 22 is inserted, the mark 31M (see FIG. 3B) of the current measuring portion main body 31 and the male screw portion 224 (see FIG. 2B) in the second magnetic steel piece portion 22. ) Are aligned so that the side with the Thereby, the polarity of magnetization can be grasped. Then, the value and polarity of the magnetizing current of the second magnetic steel piece 22 are obtained from the magnitude of the angle at which the magnetic needle 321 is swung from the reference position and the direction of the wobbling.

  FIG. 7 is a diagram illustrating the relationship between the magnetizing current and the residual magnetism in the current measurement system according to the first embodiment.

In FIG. 7, the horizontal axis is the magnetization current i [A], and the vertical axis is the residual magnetism B [wb / m ² ]. In FIG. 7, L1 shows the case of the first magnetic steel piece portion 21, and L2 shows the case of the second magnetic steel piece portion 22.

  As shown in FIG. 7, in the first range R <b> 1 where the magnetizing current i is low, the rate at which the remanent magnetism B increases as the magnetizing current i increases is higher in the case of the first magnetic steel piece part 21 (L <b> 1). It is larger than the case of the second magnetic steel piece 22 (L2). For this reason, in this embodiment, the magnetization current i in the first range R1 can be obtained with high accuracy from the residual magnetism B of the first magnetic steel piece portion 21.

  On the other hand, in the second range R2 in which the magnetization current i is higher than the first range R1, in the case of the first magnetic steel piece portion 21 (L1), the residual magnetism B does not increase as the magnetization current i increases. Saturates to a certain value. For this reason, in the case of the first magnetic steel piece portion 21 (L1), the magnetization current i in the second range R2 cannot be obtained from the residual magnetism B. However, in the case of the second magnetic steel piece portion 22 (L2), the residual magnetism B increases according to the magnetization current i and does not saturate in the second range R2 as well as the first range R1. That is, the magnetization current reaching saturation magnetism in the second magnetic steel piece portion 22 is larger than the magnetization current reaching saturation magnetism in the first magnetic steel piece portion 21. For this reason, in this embodiment, in addition to the magnetization current i in the first range R1, the magnetization current i in the second range R2 can be obtained from the residual magnetism B of the second magnetic steel piece portion 22.

[B-5] Demagnetization of Magnetic Steel Piece 2 Next, the magnetic steel piece 2 is demagnetized.

  Here, first, the demagnetizing section 4 (see FIG. 4) is prepared, and a power cable (not shown) is electrically connected to a pair of power terminals 411 provided in the demagnetizing section 4.

  Then, the power switch 412 of the demagnetizing unit 4 is switched on to supply current to the degaussing coil 421C. Then, in a state where current is supplied to the demagnetizing coil 421C, the first magnetic steel piece portion 21 and the second magnetic steel piece portion 22 constituting the magnetic steel piece 2 are respectively connected from one end portion of the insertion tube 422 of the demagnetizing portion 4. Insert inside and pull out from the other end.

  Then, after switching the power switch 412 to OFF, the magnetizing current is zero for each of the first magnetic steel piece part 21 and the second magnetic steel piece part 22 using the current measuring part 3 (see FIG. 3). Is confirmed, the degaussing process is completed. If the magnetic current is not zero, the demagnetization process is repeated as described above.

  After erasing the residual magnetism from the magnetic steel piece 2, the magnetic steel piece 2 can be inserted into the magnetizing coil 14 of the magnetized portion 1 (see FIG. 1) and the magnetization current can be measured again. .

[C] Summary As described above, in the current measurement system of the present embodiment, the magnetic steel piece 2 (see FIG. 2) is inserted into the magnetizing coil 14 constituting the magnetized portion 1 (see FIG. 1), and magnetization is performed. The magnetic steel piece 2 is magnetized by the current flowing through the coil 14. And the magnetizing current of the magnetized magnetic steel piece 2 is measured by the current measuring unit 3 (see FIG. 3). Here, the magnetic steel piece 2 has a first magnetic body 211 and a second magnetic body 221, and each of the first magnetic body 211 and the second magnetic body 221 is located inside the magnetization coil 14. They are installed side by side in the axial direction (see FIG. 5), and both are magnetized simultaneously by the current flowing through the magnetizing coil.

  In the present embodiment, both the first magnetic body 211 and the second magnetic body 221 have different relationships (BH characteristics) between the magnetic flux density B and the magnetic field strength H. Therefore, as shown in FIG. 7, the magnetization current at which the second magnetic body 221 reaches saturation magnetism is larger than the magnetization current at which the first magnetic body 211 reaches saturation magnetism. As a result, with respect to the first range R1 where the magnetization current i is low, the magnetization current i can be obtained with high accuracy from the residual magnetism B of the first magnetic steel piece portion 21. Further, in the second range R2 in which the magnetization current i is higher than the first range R1, the magnetization current i cannot be obtained from the residual magnetism B of the first magnetic steel piece portion 21, but the residual magnetism of the second magnetic steel piece portion 22 is determined. From B, the magnetization current i in the second range R2 can be obtained.

  Therefore, in this embodiment, since the magnetic steel piece 2 has the plurality of magnetic bodies 211 and 221 having different BH characteristics, the measurable range of the magnetizing current can be widened and the measurement accuracy can be increased. Can be improved.

  In the present embodiment, as shown in FIG. 5, the first magnetic body 211 is provided inside the first insulator 213 and constitutes the first magnetic steel piece portion 21. And the 2nd magnetic body 221 is provided in the inside of the 2nd insulator 223, and comprises the 2nd magnetic steel piece part 22. FIG. And both the 1st magnetic steel piece part 21 and the 2nd magnetic steel piece part 22 are mutually detachable. For this reason, in this embodiment, a remanent magnetism can be measured separately, without mutual remanent magnetism interfering between the 1st magnetic steel piece part 21 and the 2nd magnetic steel piece part 22. FIG. Therefore, this embodiment can improve the accuracy of measurement.

  In this embodiment, the 1st magnetic steel piece part 21 is provided with the 1st magnetic shielding body 212 in the edge part of the side by which the 2nd magnetic steel piece part 22 is attached or detached. Moreover, the 2nd magnetic steel piece part 22 is provided with the 2nd magnetic shielding body 222 in the edge part by which the 1st magnetic steel piece part 21 is attached or detached. The first magnetic shield 212 and the second magnetic shield 222 are magnetic bodies having higher magnetic permeability than the first magnetic body 211 and the second magnetic body 221. For this reason, in this embodiment, since magnetism is shielded between the 1st magnetic steel piece part 21 and the 2nd magnetic steel piece part 22, magnetization is performed independently by each. Further, the first magnetic steel piece portion 21 and the second magnetic steel piece portion 22 do not interfere with each other's residual magnetism. Therefore, this embodiment can improve the accuracy of measurement.

  In the present embodiment, the magnetism is shielded between the first magnetic body 211 and the second magnetic body 221 by the first magnetic shield 212 and the second magnetic shield 222 in the magnetic steel piece 2. For this reason, the distance between the 1st magnetic body 211 and the 2nd magnetic body 221 can be shortened. Therefore, the magnetic steel piece 2 can be reduced in size.

[D] Modified Example As described above, in the present embodiment, the magnetic steel piece 2 has been described with respect to the case where the magnetic permeability is different between the first magnetic body 211 and the second magnetic body 221, but this is not a limitation. A material having the same magnetic permeability may be used for both the first magnetic body 211 and the second magnetic body 221, and in that case, the first magnetic body 211 and the second magnetic body 211 are different from each other by making the magnetic path lengths different from each other. BH characteristics can be made different from those of the magnetic body 221.

  The following equation (1) is established between the magnetic flux density B and the magnetic field strength H. Each factor shown in Formula (1) is as follows.

  B = μH = μ · (nI / d) = μ ′ · nI (1)

  B: magnetic flux density (residual magnetism), μ: magnetic permeability, H: strength of magnetic field generated by the magnetizing coil (H = nI / d), n: number of turns of the magnetizing coil, d: magnetic path length (the length of the magnetic material) ), I: value of current flowing through the magnetizing coil, μ ′: apparent permeability (μ′≡μ / d)

  As can be seen from the above formula (1), in order to make the BH characteristics different between the first magnetic body 211 and the second magnetic body 221, the first magnetic body 211 and the second magnetic body 221 are different. In addition to changing the magnetic permeability μ between each other, the magnetic path lengths d may be changed from each other. For example, when materials having the same magnetic permeability μ are used for both the first magnetic body 211 and the second magnetic body 221, the magnetic path length d of the first magnetic body 211 is made shorter than that of the second magnetic body 221. As a result, a result similar to the result shown in FIG. 7 can be obtained.

  In this embodiment, the magnetic steel piece 2 includes the first magnetic body 211 and the second magnetic body 221 as the magnetic bodies magnetized inside the magnetizing coil 14 (FIGS. 2 and 5). Reference), but not limited to this. The magnetic steel piece may include three or more magnetic bodies as the magnetic body magnetized inside the magnetizing coil 14.

  In the present embodiment, the first magnetic steel piece portion 21 and the second magnetic steel piece portion 22 constituting the magnetic steel piece 2 are manufactured by molding a resin around a magnetic body or the like (FIGS. 2 and 5). Reference), but not limited to this. You may form each of the 1st magnetic steel piece part 21 and the 2nd magnetic steel piece part 22 by accommodating a magnetic body etc. in the inside of the insulation container previously shape | molded using the insulator.

  In the present embodiment, in the magnetized portion 1, the magnetizing coil 14 has one turn (see FIG. 1), but is not limited thereto. The number of turns may be two or more.

  In the present embodiment, the current measuring unit 3 (see FIG. 3) has an azimuth magnetometer 32, and the magnetic current of the magnetic steel piece 2 is obtained from the magnitude of the magnetic needle 321 swinging in the azimuth magnetometer 32. Not limited to this. You may measure the magnetic current of the magnetic steel piece 2 using measuring instruments, such as a Gauss meter using a Hall sensor, a flux meter using a search coil, a magnet analyzer, and a magnetic sheet.

Second Embodiment
[A] Configuration, etc. FIGS. 8 and 9 are views showing a magnetic steel piece in the current measurement system according to the second embodiment.

  In FIG. 8, (a) is a top view and (b) is a side view as in FIG. FIG. 9 is a cross-sectional view, similar to FIG. 5, showing each of the first magnetic steel piece portion, the second magnetic steel piece portion, and the third magnetic steel piece portion constituting the magnetic steel piece.

  In this embodiment, as shown in FIGS. 8 and 9, the magnetic steel piece 2 is different from the first embodiment (see FIGS. 2 and 5). The present embodiment is the same as that of the first embodiment except for this point and points related thereto. For this reason, in this embodiment, the description overlapping with the above embodiment is omitted as appropriate.

  As shown in FIGS. 8 and 9, the magnetic steel piece 2 includes a first magnetic steel piece portion 21, a second magnetic steel piece portion 22, and a third magnetic steel piece portion 23.

  As shown in FIG. 8, in the magnetic steel piece 2, each of the first magnetic steel piece portion 21, the second magnetic steel piece portion 22, and the third magnetic steel piece portion 23 is a cylindrical body, and the first magnetic steel piece The piece part 21 and the second magnetic steel piece part 22 are connected via a third magnetic steel piece part 23.

  Moreover, as shown in FIG. 9, in the magnetic steel piece 2, each of the 1st magnetic steel piece part 21, the 2nd magnetic steel piece part 22, and the 3rd magnetic steel piece part 23 is detachable.

  The 1st magnetic steel piece part 21 has the 1st magnetic body 211, the 1st insulator 213, and the 1st male thread part 214b, as shown to Fig.9 (a). In the first magnetic steel piece portion 21, the first magnetic body 211 is provided inside the first insulator 213. The first male threaded portion 214b is provided on the surface (lower surface) of the end portion of the first magnetic steel piece portion 21 where the third magnetic steel piece portion 23 is attached and detached. In the present embodiment, unlike the above-described embodiment, the magnetic shield is not provided in the first magnetic steel piece portion 21.

  The 2nd magnetic steel piece part 22 has the 2nd magnetic body 221, the 2nd insulator 223, and the 2nd male thread part 224, as shown in FIG.9 (c). In the second magnetic steel piece 22, the second magnetic body 221 is provided inside the second insulator 223. Further, the second male threaded portion 224 is provided on the surface (upper surface) of the end portion of the second magnetic steel piece portion 22 where the third magnetic steel piece portion 23 is attached and detached. In the present embodiment, unlike the above-described embodiment, the magnetic shield is not provided in the second magnetic steel piece portion 22.

  As shown in FIG. 9B, the third magnetic steel piece portion 23 includes a magnetic shield 232, a third insulator 233, and first and second female screw portions 234A and 234B. In the third magnetic steel piece portion 23, a magnetic shield 232 is provided inside the third insulator 233. Further, the first female thread portion 234A is provided on the surface (upper surface) of the end portion of the third magnetic steel piece portion 23 where the first magnetic steel piece portion 21 is attached and detached. The second female thread portion 234B is provided on the surface (lower surface) of the end portion of the third magnetic steel piece portion 23 where the second magnetic steel piece portion 22 is attached and detached.

  As shown in FIG. 9, the first magnetic steel piece portion 21 and the third magnetic steel piece portion 23 are connected by screwing the first male screw portion 214b into the first female screw portion 234A. Further, the second magnetic steel piece portion 22 and the third magnetic steel piece portion 23 are connected by screwing the second male screw portion 224 into the second female screw portion 234B.

  Among the magnetic steel pieces 2, both the first magnetic body 211 and the second magnetic body 221 are similar to the above embodiment in the relationship between the magnetic flux density (B) and the magnetic field strength (H) ( BH characteristics) are different from each other. The magnetic shield 232 is a magnetic body having a larger magnetic permeability than the first magnetic body 211 and the second magnetic body 221. In addition, each of the first insulator 213, the second insulator 223, and the third insulator 233 is formed using an insulating material as in the above embodiment. Each of the 1st magnetic steel piece part 21, the 2nd magnetic steel piece part 22, and the 3rd magnetic steel piece part 23 is manufactured by molding an insulating material around a magnetic body etc. similarly to said embodiment. Is done.

  Similarly to the case of the above-described embodiment, when the magnetic steel piece 2 is inserted into the magnetization coil 14 of the magnetized portion 1 (see FIG. 1), the first magnetic body 211 and the second magnetic body 221 Both are arranged in the axial direction of the magnetizing coil 14. When a current flows through the magnetizing coil 14 in a state where the magnetic steel piece 2 is installed inside the magnetizing coil 14, both the first magnetic body 211 and the second magnetic body 221 are simultaneously in the magnetic steel piece 2. Magnetized. At this time, each of the first magnetic body 211 and the second magnetic body 221 is magnetized according to the BH characteristic, and retains residual magnetism having different values after magnetization.

  As shown in FIG. 9, in the magnetic steel piece 2, magnetism is shielded between the first magnetic body 211 and the second magnetic body 221 by the magnetic shield 232. For this reason, the residual magnetism of the first magnetic body 211 and the residual magnetism of the second magnetic body 221 are not interfered with each other.

  The magnetic steel piece 2 is taken out from the inside of the magnetizing coil 14 after being magnetized inside the magnetizing coil 14 in the same manner as in the above embodiment. After the first magnetic steel piece portion 21, the second magnetic steel piece portion 22 and the third magnetic steel piece portion 23 connected in the magnetic steel piece 2 are separated, the first magnetic steel piece portion 21 is separated. And the respective magnetizing currents of the second magnetic steel piece 22 are obtained.

[B] Summary As described above, in the current measurement system of the present embodiment, the magnetic shield 232 has the third magnetic steel piece portion 23 provided inside the third insulator 233 (see FIGS. 8 and 9). ). The 3rd magnetic steel piece part 23 is installed between the 1st magnetic steel piece part 21 and the 2nd magnetic steel piece part 22, and each of the 1st magnetic steel piece part 21 and the 2nd magnetic steel piece part 22 is provided. On the other hand, it is detachable. For this reason, in this embodiment, since the magnetism is shielded by the magnetic shield 232 between the first magnetic steel piece portion 21 and the second magnetic steel piece portion 22, magnetization is performed independently of each other, Do not interfere with each other's residual magnetism. In this embodiment, the residual magnetism of each of the first magnetic steel piece portion 21 and the second magnetic steel piece portion 22 without being affected by the magnetic shield 232 by removing the third magnetic steel piece portion 23. Can be measured. Therefore, this embodiment can improve the accuracy of measurement.

<Others>
Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Magnetizing part, 2 ... Magnetic steel piece, 3 ... Current measuring part, 4 ... Demagnetizing part, 5 ... Lightning arrester, 6 ... Support stand, 7 ... Discharge counting part, 11 ... Support part, 11H ... Through-hole, 12A, 12B ... support insulator, 13A, 13B ... connection terminal, 14 ... magnetization coil, 21 ... first magnetic steel piece part 21M ... mark, 22 ... second magnetic steel piece part, 23 ... third magnetic steel piece part, 31 ... current Measurement unit main body, 31 ... insertion port, 31M ... mark, 32 ... azimuth magnetometer, 41 ... demagnetization unit main body, 42 ... degaussing coil unit, 51 ... ground terminal, 81-83 ... conductor, 131A, 131B ... conductive plate, 132A , 132B ... fixing plate, 141 ... convex part, 211 ... first magnetic body, 212 ... first magnetic shield, 213 ... first insulator, 214 ... female screw part, 214b ... male screw part, 221 ... second magnetic substance, 222 ... second magnetic shield, 223 ... second insulator, 224 ... male thread portion, 23 A ... first female screw portion, 234B ... second female screw portion, 321 ... magnetic needles, 322 ... scale plate, 411 ... power source terminal, 412 ... power switch, 421 ... support portion, 421C ... degaussing coil, 422 ... insertion tube

Claims (10)

A magnetic steel piece to be inserted inside the magnetizing coil,
A first magnetic body;
A second magnet that is installed alongside the first magnetic body in the axial direction of the magnetization coil inside the magnetization coil, and is magnetized simultaneously with the first magnetic body by a magnetic field generated when a current flows through the magnetization coil. Has a body and
The first magnetic body and the second magnetic body are characterized in that a relationship between magnetic flux density and magnetic field strength is different from each other.
Magnetic steel strip. A first magnetic steel piece portion in which the first magnetic body is provided inside an insulator;
The second magnetic body has a second magnetic steel piece portion provided inside the insulator,
Both the first magnetic steel piece part and the second magnetic steel piece part are detachable from each other,
The magnetic steel piece according to claim 1. The first magnetic steel piece is
A first magnetic shield provided at an end of the side on which the second magnetic steel piece is attached and detached;
The second magnetic steel piece is
It has the 2nd magnetic shield provided in the end by the side where the 1st magnetic steel piece part is attached or detached,
The magnetic steel piece according to claim 2. The first magnetic shield and the second magnetic shield are magnetic bodies having a larger permeability than the first magnetic body and the second magnetic body,
The magnetic steel piece according to claim 3. The magnetic shield has a third magnetic steel piece provided inside the insulator;
The third magnetic steel piece part is disposed between the first magnetic steel piece part and the second magnetic steel piece part inside the magnetizing coil, and the first magnetic steel piece part and the second magnetic steel part. It is detachable with respect to each of the one part,
The magnetic steel piece according to claim 2. The magnetic shield is a magnetic body having a larger magnetic permeability than the first magnetic body and the second magnetic body,
The magnetic steel piece according to claim 5. Both the first magnetic body and the second magnetic body have different magnetic permeability,
The magnetic steel piece according to any one of claims 1 to 6. Both the first magnetic body and the second magnetic body have different magnetic path lengths,
The magnetic steel piece according to any one of claims 1 to 7. A magnetizing coil;
A magnetic steel piece inserted into the magnetized coil;
A current measuring unit that measures a magnetization current of the magnetic steel piece magnetized by a current flowing through the magnetization coil inside the magnetization coil; and
The magnetic steel pieces are
A first magnetic body;
A second magnetic body that is installed alongside the first magnetic body in the axial direction of the magnetization coil inside the magnetization coil, and is magnetized simultaneously with the first magnetic body by a current flowing through the magnetization coil;
The first magnetic body and the second magnetic body are characterized in that a relationship between magnetic flux density and magnetic field strength is different from each other.
Current measurement system. Comprising a degaussing coil for demagnetizing residual magnetism of the magnetic steel pieces,
The current measurement system according to claim 9.

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