JP2013231625A - Clamping impedance measuring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the flowing of a leakage magnetic flux from an injection clamp part side to a detection clamp part side further.SOLUTION: In joint surfaces of one first split piece 12a and the other first split piece 12b constituting the injection clamp part of a clamp part, fitting parts B and C extending toward the respective joint surfaces to overlap each other in the joined states of the respective first split pieces 12a and 12b are formed. In the joint surfaces of magnetic shield materials 17a and 17b, fitting parts E and F extending toward the respective joint surfaces to overlap each other in the joined states of the respective magnetic shield materials 17a and 17b are formed. An area of the overlapping part of the fitting part E in the jointed states of the magnetic shield materials 17a and 17b is defined wider than that of the overlapping part of the fitting part B, and an area of the overlapping part of the fitting part F is defined wider than that of the overlapping part of the fitting part C.

Description

  The present invention relates to a clamp-type impedance measuring apparatus that measures the impedance of a loop to be measured.

  As this type of impedance measuring apparatus, the applicant has already proposed the impedance measuring apparatus disclosed in Patent Document 1 below. This measuring apparatus includes a clamp part and an apparatus main body part, and is configured to be able to measure the impedance (the resistance value of the loop resistance) of a measuring object circuit as a measuring object loop.

  The clamp part includes an injection clamp part, a detection clamp part, and a housing. In addition, the injection clamp portion has a first annular core divided into two and a first winding wound around the first annular core. Similarly, the detection clamp portion has a second annular core divided into two and a second winding wound around the second annular core. In addition, the injection clamp part and the detection clamp part are housed together in a clamp-type resin housing whose tip can be freely opened and closed, and the first annular core and the second annular core are simultaneously opened and closed as the housing opens and closes. It is configured to open and close. With this configuration, when the housing is in an open state, the wiring that forms part of the circuit to be measured is introduced to the inside of the housing, so that the inside of each of the first and second annular cores in the open state is When the wiring is introduced and the housing is closed in this state, the wiring is simultaneously clamped by the closed first annular core and the second annular core, that is, the wiring is clamped by the clamp portion. It becomes a state.

  By the way, in this way, in the clamp part configured to arrange the injection clamp part and the detection clamp part in one housing, in the first annular core constituting the injection clamp part (in the clamp state in which the wiring is clamped) The leakage magnetic flux generated at this joining part due to the fact that the magnetic resistance at the part where the first annular core divided into two parts is joined (fitted) is larger than the magnetic resistance of the other part Into the second annular core of the detection clamp part.

  In order to reduce the inflow of leakage magnetic flux from the injection clamp part side into the second annular core of the adjacent detection clamp part, the applicant of the present application has omitted the illustration of the housing in FIG. As shown in FIG. 5A, a step (lengthwise direction of the annular core) is formed on the surface of each joint portion of the first annular core 52 (the core divided into two semi-annular divided pieces 52a and 52b) of the injection clamp portion 51. And a structure in which the steps are overlapped (engaged) with each other at the time of joining, so that the magnetic resistance at the joining portion of the first annular core 52 is reduced, and leakage from this joining portion is achieved. By reducing the magnetic flux and disposing the magnetic shield materials 57 (57a, 57b) and 67 (67a, 67b) between the injection clamp 51 and the detection clamp 61, the injection clamp 51 side We are developing an impedance measuring apparatus employing the configuration to reduce the flow of leakage flux to La detecting the clamp portion 61 side. In FIG. 10, together with the magnetic shield material 57 (57a, 57b), the magnetic shield material (magnetic shield material 56 (56a, 56b), magnetic shield material 58 (58a, 58b), and magnetic shield material 59 (59a, 59b). ) Are arranged on the split pieces 52a and 52b to cover the first annular core 52 with these magnetic shield materials, and together with the magnetic shield material 67 (67a and 67b), the magnetic shield material (magnetic shield material 66 (66a and 66b) ), A magnetic shield material 68 (68a, 68b) and a magnetic shield material 69 (69a, 69b)) are arranged on the split pieces 62a, 62b, and the second annular core 62 is covered with these magnetic shield materials. Yes.

JP 2009-216618 A (page 4, FIG. 1)

  However, the impedance measuring apparatus developed by the applicant of the present application has the following problems to be improved. That is, in this impedance measuring apparatus, by adopting the above-described configuration, leakage magnetic flux is generated from the joined portion of the first annular core 52 and leakage magnetic flux flows from the injection clamp portion 51 side to the detection clamp portion 61 side. However, it is preferable that the inflow of leakage flux from the injection clamp part 51 side to the detection clamp part 61 side can be further reduced by the magnetic shield material.

  The present invention has been made to improve such a problem, and provides a clamp-type impedance measuring apparatus including a clamp portion that can further reduce the inflow of leakage magnetic flux from the injection clamp portion side to the detection clamp portion side. The main purpose.

  In order to achieve the above object, a clamp-type impedance measuring apparatus according to claim 1 includes an injection clamp portion having a first annular core divided into two semi-annular first divided pieces, and two semi-annular second divided pieces. A detection clamp part having a second annular core divided into pieces, and a second one of the two second divided pieces on the side of the first divided piece of one of the two first divided pieces. A first core holding part that accommodates the divided pieces in a state where the divided pieces are arranged side by side, and the two second divided pieces on the side of the other first divided piece of the two first divided pieces. The other second divided pieces are arranged side by side, and each of the divided pieces is accommodated and configured to be able to be joined and separated from the first core holding portion. In the joined state, the divided pieces to be accommodated are accommodated in the first core holding portion. The second core holding part to be joined to the corresponding divided piece among the divided pieces, and the injection to the loop to be measured clamped by the first core holding part and the second core holding part in the joined state The impedance of the measurement target loop is measured based on the voltage value of the AC voltage injected from the clamp unit and the current value of the AC current flowing in the measurement target loop detected by the detection clamp unit when the AC voltage is injected. A clamp-type impedance measuring device including a processing unit, wherein the semi-annular first measuring unit disposed between the one first divided piece and the one second divided piece in the first core holding unit. 1 magnetic shield material and a semi-annular shape disposed between the other first divided piece and the other second divided piece in the second core holding portion, and the first A holding part and the second core holding part in the joined state, the second magnetic shield material joined to the first magnetic shield material, the one first divided piece and the other first divided piece Each of the joint surfaces is formed with one or two or more first fitting portions that extend toward the joint surfaces and overlap each other in the joined state of the first divided pieces. One or two or more second fitting portions that extend toward the joint surfaces of the shield material and the second magnetic shield material and overlap each other in the joint state of the magnetic shield materials. Is formed, and the area of the overlapping portion of the second fitting portion in the joined state of the magnetic shield materials is defined wider than the area of the overlapping portion of the first fitting portion.

  The clamp-type impedance measuring device according to claim 2 is the clamp-type impedance measuring device according to claim 1, wherein the entire overlapping portion of the first fitting portion is the same as the overlapping portion of the second fitting portion in plan view. The first fitting portion and the second fitting portion are formed so as to be included in the region.

  Moreover, the clamp type impedance measuring apparatus according to claim 3 is the clamp type impedance measuring apparatus according to claim 1 or 2, wherein each of the joining surfaces of the one second divided piece and the other second divided piece is One or two or more third fitting portions that extend toward each other's joint surfaces and overlap each other in the joined state of the respective second divided pieces are formed, and the entire overlapping portion of the third fitting portions is a flat surface. The second fitting portion and the third fitting portion are formed so as to be included in the region of the overlapping portion of the second fitting portion when viewed.

  According to the clamp-type impedance measuring apparatus according to claim 1, the area is defined between the first annular core of the injection clamp part and the second annular core of the detection clamp part so that the magnetic resistance is sufficiently low. Each of the first divided pieces of the injection clamp portion is provided with a magnetic shield material in which the second fitting portions having a larger area than the first fitting portion of the first divided piece overlap each other and the respective joining surfaces are joined. Even if leakage magnetic flux is generated at the joint portion, the magnetic shield material having low magnetic resistance shields the leakage magnetic flux, so that the inflow of the leakage magnetic flux to the detection clamp portion can be sufficiently reduced. Thereby, the measurement accuracy of impedance can be greatly improved.

  Moreover, according to the clamp type impedance measuring apparatus according to claim 2, each first fitting part of the first annular core in which leakage magnetic flux is generated can be covered with each second fitting part of the magnetic shield material in plan view. Therefore, it is possible to further reduce the inflow of the leakage magnetic flux generated in the injection clamp part to the detection clamp part. Thereby, the impedance measurement accuracy can be further improved.

  According to the clamp type impedance measuring apparatus of claim 3, each 3rd fitting part of the 2nd annular core by the side of a detection clamp part with a possibility of inflow of leakage magnetic flux is made to correspond to each 2nd of a magnetic shield material. Since it can cover with a fitting part, the inflow to the detection clamp part of the leakage magnetic flux which generate | occur | produced in the injection | pouring clamp part can be reduced further. Thereby, the impedance measurement accuracy can be further improved.

1 is an external view of a measuring device 1. FIG. One end side of each first divided piece 12a, 12b constituting the first annular core 12 of the injection clamp portion 11 and one end of each second divided piece 22a, 22b constituting the second annular core 22 of the detection clamp portion 21. FIG. 4 is an enlarged perspective view of the portion side (enlarged perspective view in a state in which illustration of the housing 31 is omitted). It is the WW sectional view taken on the line in FIG. 4 is a perspective view for explaining the structures of a first annular core 12 and a second annular core 22. FIG. FIG. 3 is an exploded perspective view for explaining the structures of a first annular core 12 and a second annular core 22. It is a perspective view for demonstrating the structure of the magnetic shielding material 16 (16a, 16b). It is a disassembled perspective view for demonstrating the structure of the magnetic shielding material 16 (16a, 16b). It is a top view of the clamp part 2 at the time of an open state (plan view of the state which abbreviate | omitted illustration of the housing 31). It is a top view of the clamp part 2 at the time of a closed state (plan view of the state which abbreviate | omitted illustration of the housing 31). It is an expansion perspective view (enlarged perspective view of the state which omitted illustration of the housing 31) of the clamp part for demonstrating the structure of the impedance measuring device which the applicant has developed.

  Hereinafter, embodiments of a clamp type impedance measuring apparatus will be described with reference to the accompanying drawings. In this example, as an example of the clamp-type impedance measuring apparatus, the resistance value of the resistance of the loop to be measured including the ground resistance which is an example of the measurement target (for example, the resistance value of the ground resistance, an example of the physical quantity (electrical parameter)) A clamp-type resistance measuring device (clamp-type ground resistance meter) 1 that measures the above will be described as an example.

  First, the configuration of the clamp-type resistance measuring device 1 (hereinafter also referred to as “measuring device 1”) will be described with reference to FIGS.

  A measuring apparatus 1 shown in FIG. 1 includes a clamp unit 2 and a main body unit 3 and is configured to be able to measure the resistance value of the measurement target loop 4 clamped by the clamp unit 2 (resistance value Rx of the ground resistance 5).

  As shown in FIGS. 1 and 2, the clamp unit 2 includes an injection clamp unit 11, a detection clamp unit 21, and a housing 31. The housing 31 includes a first housing 31a and a second housing 31b attached to the main body 3 so as to be rotatable in the same plane around the axis L defined in the main body 3. The first housing 31a and the second housing 31b are joined to each other by a biasing force of a spring (not shown) provided in the main body 3 when the opening / closing lever 3a provided in the main body 3 is not operated. It shifts to the state (closed state shown in FIG. 1). On the other hand, when the open / close lever 3a is operated and pushed into the main body 3, the first housing 31a and the second housing 31b rotate in directions away from each other and shift to an open state (not shown).

  As shown in FIGS. 2 and 3, the injection clamp unit 11 includes, as an example, a first annular core 12, a bobbin 13, a first winding 14, an insulating cover 15, and magnetic shield materials 16 (16 a, 16 b), 17 ( 17a, 17b), 18 (18a, 18b), 19 (19a, 19b). As shown in FIG. 4, the first annular core 12 is divided into two first divided pieces 12 a and 12 b that are semi-annular (in this example, arcuate) in plan view. As an example, as shown in FIG. 5, each of the first divided pieces 12a and 12b has a first magnetic flat plate PL1 formed in a semicircular shape in the plan view (an arc shape in this example) and a semicircular shape in the plan view. As shown in FIG. 4, the second magnetic flat plates PL <b> 2 formed in an arc shape in this example are alternately stacked. 4 shows a configuration in which the magnetic flat plates PL1 and PL2 are laminated one by one. In this example, as shown in FIG. 2, four magnetic flat plates PL1 and PL2 are alternately laminated as an example. The structure to be adopted is adopted.

  In this case, the first magnetic flat plate PL1 is formed using a plate material having the same thickness as the second magnetic flat plate PL2. As an example, as shown in FIGS. 4 and 5, the first magnetic flat plate PL1 has a second magnetic flat plate PL2 in a state of being laminated in the plan view of the central portion A that overlaps the second magnetic flat plate PL2. It is defined to be the same as the planar view shape of the central portion A of the flat plate PL2. In addition, the second magnetic flat plate PL2 is arranged on the one end side (upper end side in FIGS. 4 and 5) along the length direction from the central portion A to the central portion A and within the plane including the central portion A. A fitting portion (first fitting portion) B extending in FIG. On the other hand, the first magnetic flat plate PL1 is located on the other end side (the lower end side in FIGS. 4 and 5) along the length direction from the central portion A to the central portion A and in the plane including the central portion A. A fitting part (another first fitting part) C extending in FIG.

  In this way, two magnetic flat plates PL1 and PL2 having the same shape in plan view of the central part A and different only in the shape of each end are aligned (in a state in which the central parts A are aligned), for example, As shown in FIG. 5, the first divided piece 12a is formed by laminating the first magnetic flat plate PL1 with the second magnetic flat plate PL2 facing down, and conversely, for the first divided piece 12b, As shown in the figure, the first magnetic flat plate PL1 is turned down and the second magnetic flat plate PL2 is laminated thereon. As a result, the first divided piece 12a and the first divided piece 12b are arranged so that the end faces of the parts constituted by the central parts A of the magnetic flat plates PL1 and PL2 are the end faces of the first divided piece 12a and the first divided piece 12b ( When viewed as a joint surface with the mating joint piece), a fitting portion B extending toward the mating joint surface is formed on one end face (one joint face) and the other end face (the other joint surface). The fitting portion C extends toward the other joining surface of the mating member. For this reason, when the 1st division | segmentation piece 12a and the 1st division | segmentation piece 12b joined the edge parts in which the same fitting part B and C were formed, one end part side is mutual fitting part B, B is joined in a state where it is overlapped over almost the entire region, and the other end side is joined in a state where the mutual fitting portions C, C are overlapped over almost the entire region. In this case, the magnetic resistance at each joint portion of the first divided piece 12a and the first divided piece 12b can be lowered as the area of the overlapping portion (that is, the area of the contacting portion) is increased. Therefore, the area of each fitting part B, C in plan view is defined as an area where the magnetic resistance in the joined state is sufficiently low.

  As described above, each of the first divided pieces 12a and 12b has a configuration in which four magnetic flat plates PL1 and PL2 are alternately stacked. Therefore, there are two corresponding fitting portions B and C on each joint surface. The above configuration (four in this example) extends (see FIG. 2). In FIG. 2, only the fitting part B side of the first divided pieces 12a, 12b is shown. Although not shown, in the first divided pieces 12a and 12b configured by laminating the magnetic flat plates PL1 and PL2 one by one, each joint surface has only one corresponding fitting portion B and C. It becomes the structure to extend.

  The bobbin 13 is made of an insulating material such as a synthetic resin and is attached to the central portion A of the first divided pieces 12a and 12b (not shown) (as an example, attached to the first divided piece 12a). The state of being present is shown in FIG. The total number of turns of the first winding 14 is defined as a known number of turns N1, and the first winding 14 is divided into two and wound around each bobbin 13 attached to the first divided pieces 12a and 12b. (As an example, the state of being wound around the bobbin 13 of the first divided piece 12a is shown in FIG. 2). The insulating cover 15 is made of an insulating material such as synthetic resin and is attached to the first divided pieces 12a and 12b so as to cover the outer periphery of the first winding 14 (as an example, the first divided piece 12a). FIG. 3 shows a state where it is attached to the head).

  As shown in FIG. 2, the magnetic shield materials 16, 17, 18, and 19 are attached to the magnetic shield materials 16a, 17a, 18a, and 19a attached to the first divided piece 12a side, and the first divided piece 12b side. And magnetic shield materials 16b, 17b, 18b, and 19b.

  As shown in FIG. 7, each of the magnetic shield materials 16a and 16b has a first shield flat plate PL3 formed in a semi-annular shape (in this example, an arc) in plan view, and a semi-annular shape (in this example). The second shield flat plate PL4 formed in an arc shape is laminated and configured as shown in FIG. Although FIG. 6 shows a configuration in which each shield flat plate PL3, PL4 is laminated one by one, although not shown, a configuration in which a plurality of shield flat plates PL3, PL4 are alternately laminated can also be adopted. .

  In this case, the first shield flat plate PL3 is formed using a plate material having the same thickness as the second shield flat plate PL4. Further, as an example, as shown in FIGS. 6 and 7, the first shield flat plate PL3 has a plan view shape of the central portion D that overlaps the second shield flat plate PL4 in a state of being stacked with the second shield flat plate PL4. It is defined to be the same as the plan view shape of the central portion D of the flat plate PL4. In addition, the second shield flat plate PL4 is arranged on the one end portion side (the upper end portion side in FIGS. 6 and 7) along the length direction from the central portion D to the central portion D and within the plane including the central portion D. A fitting part (second fitting part) E extending in FIG. On the other hand, the first shield flat plate PL3 is disposed on the other end side (the lower end side in FIGS. 6 and 7) along the length direction from the central portion D to the central portion D and includes the central portion D. The fitting part (other 2nd fitting part) F extended in is formed.

  In this way, the two shield plates PL3 and PL4 having the same shape in plan view of the central portion D and different only in the shape of each end are aligned with each central portion D, for example, for the magnetic shield material 16a. 6 and 7, the first shield flat plate PL3 is laminated with the second shield flat plate PL4 facing down, and conversely, the magnetic shield material 16b is as shown in FIG. The second shield flat plate PL4 is laminated on the first shield flat plate PL3 facing down. Thereby, each magnetic shield material 16a, 16b uses each end surface of the site | part comprised by each center site | part D of shield flat plate PL3, PL4 as each end surface (joint surface with the other shield material) of magnetic shield material 16a, 16b. When viewed as, a fitting portion E is formed on one end face (one joining face) and extends toward the other joining face, and the other end face (the other joining face) is on the other joining face. It has the structure in which the fitting part F extended toward a joining surface was formed. For this reason, when each magnetic shield material 16a, 16b joins the edge parts in which the same fitting parts E and F were formed, the fitting parts E and E of the one end part side are almost the whole area. It joins in the state which overlapped over, and the other end part side joins in the state which the mutual fitting parts F and F overlapped over the whole region.

  As described above, the magnetic shield materials 16a and 16b have a configuration in which the shield plates PL3 and PL4 are laminated one by one. Therefore, each joint surface has only one corresponding fitting portion E and F, respectively. It is the structure extended (refer FIG. 2). In FIG. 2, only the fitting part E side of the magnetic shield materials 16a and 16b is shown. Although not shown, the magnetic shield materials 16a and 16b can be configured by alternately laminating a plurality of shield plates PL3 and PL4, and in this configuration, each joint surface has a corresponding fitting. The joining portions E and F extend by the number of sheets (a plurality of sheets).

  As shown in FIG. 2, the magnetic shield material 16a is on the non-facing surface side of the first divided piece 12a with the detection clamp portion 21, and the magnetic shield material 16b is connected to the detection clamp portion 21 on the first divided piece 12b. Each is mounted on the non-facing surface side via an insulating cover 15 (see FIG. 3). 3 shows a state where the magnetic shield material 16a is attached to the first divided piece 12a, the magnetic shield material 16b is similarly attached to the first divided piece 12b side.

  Further, as shown in FIG. 8, the shape of the fitting portions E and F of the magnetic shield materials 16 a and 16 b in plan view is such that the fitting portion E is fitted to the first divided pieces 12 a and the first divided pieces 12 b. The fitting portion F is wider than the fitting portion B, and the fitting portion F is configured to be wider than the fitting portions C of the first divided pieces 12a and the first divided pieces 12b. Thereby, also about each fitting part E and F, similarly to each fitting part B and C, it is prescribed | regulated so that the magnetic resistance in a joining state may become low enough. Moreover, the positional relationship in the planar view state with respect to each fitting part B and C of each 1st division | segmentation piece 12a and each 1st division | segmentation piece 12b of each fitting part E and F of each magnetic shielding material 16a, 16b is the same. As shown in the figure, the entire fitting part B is included in the area of the fitting part E, and the entire fitting part C is included in the area of the fitting part F.

  The magnetic shield materials 17a and 17b have the above-described configuration except that a plurality of first shield flat plates PL3 are stacked (two in this example) and a plurality of second shield flat plates PL4 are stacked (two in this example). The magnetic shield materials 16a and 16b are the same. As shown in FIG. 2, the magnetic shield material 17a faces the detection clamp portion 21 in the first divided piece 12a, and the magnetic shield material 17b faces the detection clamp portion 21 in the first divided piece 12b. Each is mounted on the surface side via an insulating cover 15 (see FIG. 3). 3 shows a state in which the magnetic shield material 17a is attached to the first divided piece 12a, the magnetic shield material 17b is similarly attached to the first divided piece 12b side. As shown in FIG. 8, the magnetic shield members 17a and 17b are mounted so as to overlap the entire corresponding magnetic shield members 16a and 16b in a plan view.

  With this configuration, the magnetic shield materials 17a and 17b are disposed between the first divided pieces 12a and 12b and the second divided pieces 22a and 22b described later which constitute the second annular core 22 of the detection clamp portion 21. The magnetic shield material 17a functions as the first magnetic shield material, and the magnetic shield material 17b functions as the second magnetic shield material, respectively, so that each joint portion of the first divided pieces 12a and 12b constituting the first annular core 12 ( Leakage of leakage magnetic flux generated in the fitting parts B and C) to the detection clamp part 21 side is directly reduced. In order to enhance the effect of this reduction, in this example, as described above, the magnetic shield members 17a and 17b are configured using a plurality of first shield plates PL3 and a plurality of second shield plates PL4. ing. In addition, when there is little leakage magnetic flux which generate | occur | produces in each junction part of the 1st division | segmentation piece 12a, 12b which comprises the 1st cyclic | annular core 12, the magnetic shielding materials 17a and 17b are made the same as the magnetic shielding materials 16a and 16b. It can also be constituted by one first shield flat plate PL3 and one second shield flat plate PL4. In addition, since the magnetic shield members 17a and 17b are configured to use a plurality of stacked first shield flat plates PL3 and a plurality of stacked second shield flat plates PL4 one by one, each joint surface has a corresponding fitting. Although only one joint portion E, F is extended, although not shown, the magnetic shield materials 17a, 17b are configured by alternately stacking the same number of shield plates PL3, PL4. In this configuration, the corresponding fitting portions E and F extend by the number of sheets (plurality) on each joint surface.

  The magnetic shield members 18a and 18b are formed of rectangular shield plates bent in advance according to the curvature of the outer peripheral surface (curved surface) of the insulating cover 15 attached to the first divided pieces 12a and 12b. Further, as shown in FIG. 3, each magnetic shield material 18 is sandwiched between the magnetic shield materials 16 and 17 on the outer peripheral surface of the insulating cover 15 and magnetically connects between the magnetic shield materials 16 and 17. It is mounted in a state of being connected to.

  The magnetic shield materials 19a and 19b are formed of rectangular shield flat plates bent in advance according to the curvature of the inner peripheral surface (curved surface) of the insulating cover 15. Further, as shown in FIG. 2, each magnetic shield material 19 is mounted on the inner peripheral surface of the insulating cover 15 in a state of being sandwiched between the magnetic shield materials 16 and 17, as shown in FIGS. Has been. In this example, each magnetic shield material 19 is magnetically connected to the magnetic shield material 17, but is mounted in a state where it is not magnetically connected to the magnetic shield material 16. Thereby, each magnetic shielding material 16,17,18,19 is comprised so that it may not function as a 1-turn winding with respect to the 1st division | segmentation piece 12a, 12b.

  As shown in FIGS. 2 and 3, the detection clamp 21 includes, for example, a second annular core 22, a bobbin 23, a second winding 24, an insulating cover 25, and magnetic shield materials 26 (26 a and 26 b) and 27 ( 27a, 27b), 28 (28a, 28b), 29 (29a, 29b). As shown in FIG. 4, the second annular core 22 includes two semicircular second divisions that are configured in the same manner as the first division pieces 12 a and 12 b using the first magnetic flat plate PL <b> 1 and the second magnetic flat plate PL <b> 2. It is divided into pieces 22a and 22b. In this example, as shown in FIG. 2, the second divided pieces 22a and 22b are configured by alternately laminating four magnetic flat plates PL1 and PL2 in the same manner as the first divided pieces 12a and 12b. Yes.

  Thus, since the 2nd division | segmentation piece 22a, 22b is comprised the same as the 1st division | segmentation piece 12a, 12b, the same fitting part (the 3rd fitting part in the detection clamp part 21) B and C is the same. When the formed end portions are joined together, one end side is joined in a state where the fitting portions B and B are overlapped over almost the entire region, and the other end side is fitted to each other. The parts C and C are joined in a state where they almost overlap each other.

  The bobbin 23 is configured in the same manner as the bobbin 13 and is mounted on each of the central portions A of the second divided pieces 22a and 22b. ). The second winding 24 has a total number of turns defined to a known number of turns N2, is divided into two, and is wound around each bobbin 23 attached to the second divided pieces 22a and 22b. (As an example, the state of being wound around the bobbin 23 of the second divided piece 22a is shown in FIG. 2). The insulating cover 25 is made of an insulating material such as a synthetic resin and is attached to the second divided pieces 22a and 22b so as to cover the outer periphery of the second winding 24 (as an example, the second divided piece 22a). FIG. 3 shows a state where it is attached to the head).

  As shown in FIG. 2, the magnetic shield materials 26, 27, 28, and 29 are attached to the magnetic shield materials 26a, 27a, 28a, and 29a attached to the second divided piece 22a side and the second divided piece 22b side. And magnetic shield materials 26b, 27b, 28b, and 29b.

  As shown in FIG. 2, the magnetic shield materials 26a and 26b are configured by laminating a first shield flat plate PL3 and a second shield flat plate PL4 one by one in the same manner as the magnetic shield materials 16a and 16b. The magnetic shield materials 26a and 26b are configured in the same manner as the magnetic shield materials 16a and 16b except that the stacking order of the first shield flat plate PL3 and the second shield flat plate PL4 is reversed. Although not shown, a configuration in which a plurality of shield plates PL3 and PL4 are alternately stacked may be employed.

  Thus, the magnetic shield materials 26a and 26b are configured in the same manner as the magnetic shield materials 16a and 16b, except that the stacking order is reversed. For this reason, when the end portions where the same fitting portions B and C are formed are joined to each other, the magnetic shielding materials 26a and 26b have the fitting portions B and B on almost one end side. It joins in the state over which it overlapped, and the other end part side is joined in the state which the mutual fitting parts C and C overlapped over substantially the whole region.

  As shown in FIG. 2, the magnetic shield material 26a is on the non-facing surface side of the second divided piece 22a with the injection clamp portion 11, and the magnetic shield material 26b is connected to the injection clamp portion 11 on the second divided piece 22b. Each is mounted on the non-facing surface side via an insulating cover 15 (see FIG. 3). FIG. 3 shows a state in which the magnetic shield material 26a is attached to the second divided piece 22a, but the magnetic shield material 26b is similarly attached to the second divided piece 22b side.

  The magnetic shield members 27a and 27b have a reverse stacking order of the first shield flat plate PL3 overlaid with a plurality (two in this example) and the second shield flat plate PL4 overlaid with a plurality (two in this example). Except for the magnetic shield material 17a and 17b. As shown in FIG. 2, the magnetic shield material 27a is opposite to the injection clamp portion 11 in the second divided piece 22a, and the magnetic shield material 27b is opposite to the injection clamp portion 11 in the second divided piece 22b. Each is mounted on the surface side via an insulating cover 25 (see FIG. 3). 3 shows a state in which the magnetic shield material 27a is attached to the second divided piece 22a, the magnetic shield material 27b is similarly attached to the second divided piece 22b side.

  With this configuration, the magnetic shield materials 27a and 27b are disposed between the second divided pieces 22a and 22b and the first divided pieces 12a and 12b constituting the injection clamp portion 11, and the magnetic shield material 27a is replaced with the other pieces. Leakage magnetic flux generated at each joint portion of the first divided pieces 12a and 12b constituting the first annular core 12 by functioning as the first magnetic shield material and the magnetic shield material 27b as the other second magnetic shield material. The leakage to the detection clamp part 21 side is directly reduced. In order to enhance the effect of this reduction, in this example, as described above, the magnetic shield members 27a and 27b are configured using a plurality of first shield plates PL3 and a plurality of second shield plates PL4. ing. When the shielding effect is sufficiently exerted by the magnetic shield materials 17a and 17b on the injection clamp portion 11 side, a configuration in which the magnetic shield materials 27a and 27b are omitted can be adopted, or the magnetic shield materials 27a and 27b can be It can also be constituted by one first shield flat plate PL3 and one second shield flat plate PL4.

  The magnetic shield members 28a and 28b are formed of rectangular shield plates bent in advance according to the curvature of the outer peripheral surface (curved surface) of the insulating cover 25 attached to the second divided pieces 22a and 22b. Further, as shown in FIG. 3, each magnetic shield material 28 is sandwiched between the magnetic shield materials 26 and 27 on the outer peripheral surface of the insulating cover 25, and the magnetic shield materials 26 and 27 are magnetically connected. It is mounted in a state of being connected to.

  The magnetic shield materials 29a and 29b are formed of rectangular shield plates bent in advance according to the curvature of the inner peripheral surface (curved surface) of the insulating cover 25. Further, as shown in FIG. 3, each magnetic shield material 29 is mounted on the inner peripheral surface of the insulating cover 25 in a state of being sandwiched between the magnetic shield materials 26 and 27. In this example, each magnetic shield material 29 is magnetically connected to the magnetic shield material 27, but is mounted in a state where it is not magnetically connected to the magnetic shield material 26. Thereby, each magnetic shielding material 26,27,28,29 is comprised so that it may not function as a 1-turn winding with respect to 2nd division | segmentation piece 22a, 22b.

  Each component (the first divided piece 12a and the magnetic shield materials 16a, 17a, 18a, 19a, etc.) on the first divided piece 12a side of the injection clamp part 11 configured as described above is the first of the detection clamp part 21. As shown in FIGS. 1 and 3, it is housed in the first housing 31a together with the respective components (second divided piece 22a and magnetic shield materials 26a, 27a, 28a, 29a, etc.) on the two divided pieces 22a side. In this case, each component on the first divided piece 12a side of the injection clamp portion 11 and each component on the second divided piece 22a side of the detection clamp portion 21 are in the thickness direction of the first divided piece 12a (in FIG. 3). Of the first housing 31a and a partition wall 32a constituting a part of the first housing 31a. In other words, in the first housing 31a, the second annular core 22 is formed on the side of one of the two first divided pieces 12a and 12b constituting the first annular core 12 at the side of the first divided piece 12a. One second divided piece 22a out of the two second divided pieces 22a and 22b is accommodated in a state of being arranged in parallel.

  In addition, each component (the first divided piece 12b and the magnetic shield materials 16b, 17b, 18b, 19b, etc.) on the first divided piece 12b side of the injection clamp part 11 is arranged on the second divided piece 22b side of the detection clamp part 21. As shown in FIG. 1, it is accommodated in the 1st housing 31b with each component (2nd division | segmentation piece 22b and magnetic shielding material 26b, 27b, 28b, 29b etc.). In this case, each component on the first divided piece 12b side of the injection clamp portion 11 and each component on the second divided piece 22b side of the detection clamp portion 21 are not shown, but the first divided piece 12a described above is not shown. In the same manner as the side, it is accommodated along the thickness direction of the first divided piece 12b and arranged in parallel via a partition wall constituting a part of the first housing 31b. That is, in the second housing 31b, the other second divided part of the two second divided pieces 22a and 22b is formed on the side of the other first divided piece 12b of the two first divided pieces 12a and 12b. It accommodates in the state in which the piece 22b was arranged in parallel.

  With this configuration, the first housing 31a of the first housing 31a and the second housing 31b that rotates in accordance with the operation of the opening / closing lever 3a and shifts from the closed state to the open state and from the closed state to the open state. Functions as the first core holding part, and the first divided piece 12a and the magnetic shield materials 16a, 17a, 18a and 19a of the injection clamp part 11 accommodated therein, and the second divided part of the detection clamp part 21 The piece 22a and the magnetic shield materials 26a, 27a, 28a, and 29a are rotatably held, while the second housing 31b functions as a second core holding portion and is accommodated therein. The piece 12b and the magnetic shield materials 16b, 17b, 18b, and 19b, the second divided piece 22b of the detection clamp portion 21, and the magnetic shield materials 26b, 27b, and 28b, And 9b rotatably hold.

  Further, the divided pieces 12a and 22a and the magnetic shield materials 16a, 17a, 26a and 27a held by the first housing 31a and the divided pieces 12b and 22b held by the second housing 31b in this way. When the first housing 31a and the second housing 31b are moved to the open state, the magnetic shield materials 16b, 17b, 26b, and 27b are separated from each other (not joined as shown in FIG. 8). When the first housing 31a and the second housing 31b are moved to the closed state, the corresponding divided pieces 12a and 12b are joined to each other as shown in FIG. The pieces 22a and 22b are joined to each other, and the corresponding magnetic shield materials 16a and 16b are joined to each other. Magnetic shield material 17a, 17b are joined together, the corresponding magnetic shield material 26a, 26b are joined together, the corresponding magnetic shield material 27a, 27b is shifted to a state of bonding together.

  As an example, the main body 3 includes a D / A conversion unit, a power amplification unit, a current detection unit, a detection unit, an A / D conversion unit, a processing unit, and an output unit (all not shown). In this case, a voltage injection unit is configured by the D / A conversion unit, the power amplification unit, and the injection clamp unit 11, and a current measurement unit is configured by the detection clamp unit 21, the current detection unit, the detection unit, and the A / D conversion unit. .

  The D / A converter converts the AC waveform data output from the processing unit into an AC voltage (analog signal) at a predetermined conversion rate and outputs the AC voltage. The power amplifying unit amplifies the AC voltage with a predetermined amplification factor to generate an AC voltage having a predetermined amplitude (voltage value V1), and the generated AC voltage is supplied to the first winding 14 of the injection clamp unit 11. Apply to. As a result, the test AC voltage Vx is injected into the measurement object loop 4 clamped by the injection clamp unit 11 and the detection clamp unit 21 as shown in FIG. In this case, the AC voltage Vx for inspection injected into the measurement target loop 4 is the AC voltage applied to the first winding 14 because the measurement target loop 4 functions as a one-turn winding in the first annular core 12. Is obtained by dividing the voltage value V1 by the number of turns N1 of the first winding 14 (Vx = V1 / N1).

  Since the measurement target loop 4 functions as a one-turn winding in the second annular core 22, the detection clamp unit 21 detects the alternating current Ix flowing through the measurement target loop 4, and detects the detected current in the second winding 24. (Current value I1 = Ix / N2) is output. The current detection unit converts this detection current into an AC voltage and outputs it. The detection unit synchronously detects the input AC voltage using the detection signal output from the processing unit (clock signal synchronized with the AC voltage generated by the injection clamp unit 11). The A / D conversion unit converts the AC voltage output from the detection unit into digital data and outputs it as current data. In this case, the current data output from the A / D converter is data representing the current value I1 of the detected current.

  The processing unit includes a CPU and a memory (both not shown), and performs an impedance measurement process (a resistance measurement process in this example). In this impedance measurement process, the processing unit executes output of AC waveform data to the injection clamp unit 11 and output of a detection signal to the detection clamp unit 21, and acquires current data output from the detection clamp unit 21. Then, the voltage value of the AC voltage Vx for inspection is calculated, and the current value of the AC current Ix is calculated based on the current value I1 of the detected current indicated by the current data and the number of turns (N2) of the second winding 24. (Ix = I1 × N2) is calculated. The processing unit calculates the resistance value Rx of the measurement target loop 4 by dividing the calculated voltage value of the test AC voltage Vx by the current value of the AC current Ix, and outputs the calculated resistance value Rx to the output unit. Output to. An output part is comprised with a liquid crystal display as an example, and displays the result (resistance value Rx) of an impedance measurement process.

  Thus, in this measuring apparatus 1, the open / close lever 3a is operated to shift the first housing 31a and the second housing 31b to the open state, and the measurement target loop 4 is placed between the first housing 31a and the second housing 31b. Then, the operation with respect to the opening / closing lever 3a is released and the first housing 31a and the second housing 31b are moved to the closed state, whereby the injection clamp unit 11 and the detection clamp unit 21 are clamped to the measurement target loop 4. In this clamped state, the first divided piece 12a of the injection clamp part 11, the magnetic shield material 16a and the magnetic shield material 17a, and the detection clamp part 21 which are accommodated in the first housing 31a and held by the first housing 31a. The second divided piece 22a, the magnetic shield material 26a and the magnetic shield material 27a are accommodated in the second housing 31b and held by the second housing 31b. The corresponding first divided piece 12b and magnetic shield of the injection clamp portion 11 held by the second housing 31b. The material 16b and the magnetic shield material 17b are joined to the corresponding second divided piece 22b, the magnetic shield material 26b, and the magnetic shield material 27b of the detection clamp portion 21, respectively.

  Further, in this joined state, the first divided piece 12a and the first divided piece 12b have the fitting portions B and B overlap each other over almost the whole area on one end side and are fitted to each other on the other end side. The parts C and C are overlapped over almost the entire area. Similarly, in the second divided piece 22a and the second divided piece 22b, the fitting portions B and B overlap with each other almost on the one end side, and the fitting portions C and C on the other end side overlap each other. Are overlapped over almost the entire region. In addition, each of the magnetic shield materials 16a and 16b has a fitting part E and E (fitting part E defined in a larger area than the fitting part B) overlapped over almost the whole area on one end side. On the other end side, the fitting parts F and F (fitting part E defined in an area wider than the fitting part C) are overlapped over almost the entire region. Similarly, each of the other magnetic shield materials 17a and 17b, the magnetic shield materials 26a and 26b, and the magnetic shield materials 27a and 27b also have their fitting portions E and E extending over almost the entire region on one end side. It overlaps and it will be in the state which the mutual fitting part F and F overlapped over the whole region in the other end part side.

  Therefore, according to this measuring device 1, the first annular core 12 (each first divided piece 12a, 12b) of the injection clamp part 11 and the second annular core 22 (each second divided piece 22a, 22b) of the detection clamp part 21 are provided. ) Between the fitting portions E and E having a larger area than the fitting portion B of the first divided pieces 12a and 12b whose area is defined so that the magnetic resistance is sufficiently low, and one end portion side is The fitting portions F, F having larger areas than the fitting portions C of the first divided pieces 12a, 12b whose areas are defined so that the magnetic resistance is sufficiently low are overlapped, and the other end side is joined. Since the magnetic shielding materials 17a and 17b are disposed (in this example, the magnetic shielding materials 27a and 27b are also disposed), the joining portions of the first divided pieces 12a and 12b of the injection clamp portion 11 are provided. When leakage magnetic flux occurs However, the magnetic shield materials 17a and 17b (in this example, the magnetic shield materials 27a and 27b in this example) having low magnetic resistance shield the leakage magnetic flux, so that the second annular shape of the leakage flux detection clamp portion 21 is provided. The inflow to the core 22 can be sufficiently reduced. Thereby, the measurement accuracy of the resistance value Rx can be greatly improved.

  Moreover, in this measuring apparatus 1, as shown in FIG. 9, in the closed state of the clamp part 2, each fitting part B in the 1st cyclic | annular core 12 (each 1st division | segmentation piece 12a, 12b) of the injection clamp part 11 is shown. , B in the whole (in this example, almost the entire area of the fitting portion B) in plan view, the overlapping portions of the corresponding fitting portions E, E in the magnetic shield materials 17a, 17b (in this example, The entire overlapping portion of each fitting portion C, C included in the first annular core 12 (each first divided piece 12a, 12b) of the injection clamp portion 11 (substantially the entire area of the fitting portion E) ( In this example, the substantially entire region of the fitting portion C is an overlapping portion of the corresponding fitting portions F and F in the magnetic shield materials 17a and 17b in the plan view (in this example, almost the entire region of the fitting portion F). ), The fitting portions B, C, E, and F are formed.

  Therefore, according to this measuring apparatus 1, each fitting part B and B of the 1st annular core 12 (each 1st division | segmentation piece 12a, 12b) which a leakage magnetic flux generate | occur | produces each fitting to which magnetic shielding material 17a, 17b respond | corresponds. Covering with the joint portions E and E, the respective fitting portions C and C of the first annular core 12 (the first divided pieces 12a and 12b) are respectively fitted with the corresponding fitting portions F and F of the magnetic shield materials 17a and 17b. Since it can cover, the inflow to the detection clamp part 21 of the leakage magnetic flux which generate | occur | produced in the injection | pouring clamp part 11 can be reduced further. Thereby, the measurement accuracy of the resistance value Rx can be further improved.

  Moreover, in this measuring apparatus 1, when the clamp part 2 is in the closed state, the second divided piece 22a and the second divided piece 22b constituting the second annular core 22 of the detection clamp part 21 are also fitted to each other on one end side. The parts B and B are overlapped over almost the entire region, and the fitting parts C and C are overlapped over the entire region on the other end side, and the entire overlapping part of the fitting parts B and B ( In this example, the substantially entire region of the fitting part B) is in the region of the overlapping portions of the corresponding fitting parts E, E on the magnetic shield materials 17a, 17b (in this example, almost the entire region of the fitting part E). And the entire overlapping portion of each of the fitting portions C and C (in this example, substantially the entire area of the fitting portion C) of the corresponding fitting portions F and F in the magnetic shield materials 17a and 17b. It is included in the region of the overlapping portion (in this example, substantially the entire area of the fitting portion E).

  Therefore, according to this measuring apparatus 1, each fitting part B and B of the 2nd annular core 22 (each 2nd division | segmentation piece 22a, 22b) with a possibility of inflow of a leakage magnetic flux corresponds to magnetic shielding material 17a, 17b. The fitting portions E and E are covered with the fitting portions C and C of the second annular core 22 (second divided pieces 22a and 22b), and the fitting portions F corresponding to the magnetic shield materials 17a and 17b. , F, the leakage flux generated in the injection clamp part 11 can be further reduced from flowing into the detection clamp part 21. Thereby, the measurement accuracy of the resistance value Rx can be further improved.

  In addition, it is not limited to said structure. For example, in the above configuration, in order to reduce the product cost, the first annular core 12 and the second annular core 22 are configured by a common first magnetic flat plate PL1 and second magnetic flat plate PL2, and each magnetic shield material 16 ( 16a, 16b), 17 (17a, 17b), 26 (26a, 26b), 27 (27a, 27b) are also constituted by the common shield plates PL3, PL4. The shapes of the two types of magnetic flat plates used are different from the shapes of the first magnetic flat plate PL1 and the second magnetic flat plate PL2 used in the first annular core 12, and the plan view shape of the second annular core 22 is changed to the first annular core. 12 different from the shape in plan view, and the shape of two types of shield flat plates used in each magnetic shield material 26 (26a, 26b), 27 (27a, 27b). , 16b), 17 (17a, 17b), different from the shape of the first shield flat plate PL3 and the second shield flat plate PL4, the plane of each magnetic shield material 26 (26a, 26b), 27 (27a, 27b) It is also possible to adopt a configuration in which the viewing shape is different from the planar viewing shape of each magnetic shield material 16 (16a, 16b), 17 (17a, 17b).

  Further, the two fitting portions B, C, E, and F are formed by laminating two flat plates (magnetic flat plates PL1 and PL2 and shield flat plates PL3 and PL4) having different end shapes when viewed in plan. Although the example which employs the above configuration is described above, the end faces (joint faces) of one semi-annular core material are subjected to cutting or the like, whereby the fitting portions B, C, E, F are provided on the end faces. The structure to form can also be employ | adopted.

DESCRIPTION OF SYMBOLS 1 Measuring apparatus 11 Injection clamp part 12 1st cyclic | annular core 12a, 12b 1st division | segmentation piece 17a, 17b, 27a, 27b Magnetic shield material 21 Detection clamp part 22 2nd cyclic | annular core 22a, 22b 2nd division | segmentation piece 31a 1st housing 31b Second housing B, C, E, F Fitting part

Claims (3)

An injection clamp having a first annular core divided into two semi-annular first segments;
A detection clamp part having a second annular core divided into two semi-annular second divided pieces;
Each of the two first divided pieces is accommodated in a state where one second divided piece of the two second divided pieces is juxtaposed on the side of one of the two first divided pieces. A first core holding part;
Each of the two first divided pieces is accommodated in a state where the other second divided piece of the two second divided pieces is arranged side by side on the side of the other first divided piece. The first core holding part is configured to be able to be joined / separated, and in the joined state with the first core holding part, the divided pieces to be accommodated are accommodated in the first core holding part. A second core holding part to be joined to a corresponding divided piece of each divided piece;
The voltage value of the AC voltage injected from the injection clamp unit to the loop to be measured clamped by the first core holding unit and the second core holding unit in the joined state, and the detection clamp at the time of injection of the AC voltage A clamp-type impedance measuring apparatus comprising a processing unit that measures the impedance of the measurement target loop based on the current value of the alternating current flowing through the measurement target loop detected in the unit,
A semi-annular first magnetic shield material disposed between the one first divided piece and the one second divided piece in the first core holding portion;
A semicircular ring is disposed between the other first divided piece and the other second divided piece in the second core holding portion, and the first core holding portion and the second core holding portion are arranged. A second magnetic shield material to be joined to the first magnetic shield material in the joined state with a portion;
The joint surfaces of the one first divided piece and the other first divided piece respectively extend toward the joint surfaces, and overlap each other in the joined state of the first divided pieces 1 or 2 The above first fitting portion is formed,
Each of the first magnetic shield material and the second magnetic shield material has a bonding surface that extends toward the bonding surface of the first magnetic shielding material and overlaps each other in the bonding state of the magnetic shielding materials. 2 mating parts are formed,
The clamp-type impedance measuring apparatus, wherein an area of the overlapping portion of the second fitting portion in the joined state of the magnetic shield materials is defined wider than an area of the overlapping portion of the first fitting portion.   The first fitting portion and the second fitting portion are formed such that the entire overlapping portion of the first fitting portion is included in the region of the overlapping portion of the second fitting portion in plan view. The clamp type impedance measuring apparatus according to claim 1. One or two or more of the joining surfaces of the one second divided piece and the other second divided piece extend toward the joining surface of each other and overlap each other in the joined state of the second divided pieces A third fitting portion is formed,
The second fitting portion and the third fitting portion are formed such that the entire overlapping portion of the third fitting portion is included in the region of the overlapping portion of the second fitting portion in plan view. The clamp type impedance measuring apparatus according to claim 1 or 2.

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