JPWO2016021073A1 - motor - Google Patents

Abstract

An axial dimension of a motor provided with a rotation detecting device is reduced. A motor M1 including a rotation detection device 1 includes a motor shaft SH and a motor electromagnetic unit 200 that rotates the motor shaft SH. The rotation detection device 1 is rotatable to a housing 2 and the housing 2. , The shaft 3 to which the magnets 4a to 4c are fixed, the magnetic element 51 and the coil 52 that generate a large Barkhausen effect, and the length direction of the circles of rotation of the magnets 4a to 4c is provided. Magnetic field detectors 5a to 5c that detect magnetic fields of the magnets 4a to 4c that are parallel to the tangential direction of R1 to R4 and that are fixed to the housing 2 so as to face the magnets 4a to 4c in the radial direction of the rotation locus circles R to R4. 5d.

Description

  The embodiment of the disclosure relates to a motor including a rotation detection device.

  Patent Document 1 discloses a magnetic field formed by a magnet while the first support provided with the magnet rotates with respect to the second support provided with the magnetic field detection unit as the object to be detected rotates. Describes a rotation detection device that detects a rotation state of an object to be detected by detecting a rotation angle by a magnetic field detection unit. In this rotation detection device, one end and the other end of the magnetic field detector are covered with a magnetic member.

JP 2014-48250 A

  The rotation detection device has a structure in which a first support provided with a magnet, a magnetic member, and a magnetic field detection unit are arranged in parallel in the axial direction. In a motor equipped with such a rotation detection device, there are cases where it is desired to keep the axial dimension small from the viewpoint of use environment, mountability, and the like. In this case, further optimization of the device configuration is desired.

  The present invention has been made in view of such problems, and an object thereof is to provide a motor including a rotation detection device capable of reducing the axial dimension.

  In order to solve the above-described problems, according to one aspect of the present invention, a motor including a rotation detection device includes a motor shaft and a motor electromagnetic unit that rotates the motor shaft, and the rotation detection is performed. The apparatus includes a housing, a magnet support that is rotatably supported by the housing, is coupled to the motor shaft, and has a magnet fixed thereto, a magnetic element and a coil that generate a large Barkhausen effect, and the length direction is A magnetic field detection unit for detecting a magnetic field of the magnet, which is parallel to a tangential direction of a rotation locus circle of the magnet and is fixed to the housing so as to be opposed to the magnet in a radial direction of the rotation locus circle. Applies.

  According to the motor of the present invention, the axial dimension of the rotation detecting device can be reduced.

It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on 1st Embodiment. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the same embodiment. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the same embodiment. It is explanatory drawing for demonstrating an example of the operation | movement of the magnetic field induction | guidance | derivation function of the 1st and 2nd magnetic member which concerns on the embodiment, and a magnetic field detection part. It is explanatory drawing for demonstrating an example of the operation | movement of the magnetic field induction | guidance | derivation function of the 1st and 2nd magnetic member which concerns on the embodiment, and a magnetic field detection part. It is explanatory drawing for demonstrating an example of the operation | movement of the magnetic field induction | guidance | derivation function of the 1st and 2nd magnetic member which concerns on the embodiment, and a magnetic field detection part. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification corresponding to the other example [the 1] of the structure of a magnetic member. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification. It is explanatory drawing for demonstrating an example of the operation | movement of the magnetic field induction | guidance | derivation function of the 1st and 2nd magnetic member which concerns on the modification, and a magnetic field detection part. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification corresponding to the other example [the 2] of a structure of a magnetic member. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification. It is explanatory drawing for demonstrating an example of the operation | movement of the magnetic field induction | guidance | derivation function of the 1st and 2nd magnetic member which concerns on the modification, and a magnetic field detection part. It is explanatory drawing for demonstrating an example of the operation | movement of the magnetic field induction | guidance | derivation function of the 1st and 2nd magnetic member which concerns on the modification, and a magnetic field detection part. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification corresponding to the other example [the 3] of a structure of a magnetic member. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification. It is explanatory drawing for demonstrating an example of the operation | movement of the magnetic field induction | guidance | derivation function of the 1st and 2nd magnetic member which concerns on the modification, and a magnetic field detection part. It is explanatory drawing for demonstrating an example of the operation | movement of the magnetic field induction | guidance | derivation function of the 1st and 2nd magnetic member which concerns on the modification, and a magnetic field detection part. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification corresponding to other examples [the 4] of a structure of a magnetic member. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification. It is explanatory drawing for demonstrating an example of the operation | movement of the magnetic field induction | guidance | derivation function of the 1st and 2nd magnetic member which concerns on the modification, and a magnetic field detection part. It is explanatory drawing for demonstrating an example of the operation | movement of the magnetic field induction | guidance | derivation function of the 1st and 2nd magnetic member which concerns on the modification, and a magnetic field detection part. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification which arrange | positions a magnet to the outer peripheral side of a magnetic field detection part and a magnetic member. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification. It is explanatory drawing for demonstrating an example of the operation | movement of the magnetic field induction | guidance | derivation function of the 1st and 2nd magnetic member which concerns on the modification, and a magnetic field detection part. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification which fixes a ring magnet. It is explanatory drawing for demonstrating an example of a structure of the shaft and ring magnet which concern on the modification. It is explanatory drawing for demonstrating an example of a structure of the rotation detection apparatus which concerns on the modification which covers the circumference | surroundings with a shield member. It is explanatory drawing for demonstrating an example of a structure of the motor which concerns on 2nd Embodiment. It is explanatory drawing for demonstrating an example of a structure of the motor which concerns on 3rd Embodiment.

  Hereinafter, embodiments will be described with reference to the drawings. In the present specification and drawings, components having substantially the same function are represented by the same reference numerals in principle, and repeated description of these components will be omitted as appropriate.

<1. First Embodiment>
The first embodiment will be described below.

(1-1. Configuration of rotation detection device)
First, an example of the configuration of the rotation detection device according to the present embodiment will be described with reference to FIGS. 1, 2A, and 2B. FIG. 1 is a perspective view illustrating an example of the configuration of the rotation detection device. FIG. 2A is a plan view illustrating an example of the configuration of the rotation detection device. FIG. 2B is a side view illustrating an example of the configuration of the rotation detection device. In FIG. 1 and FIG. 2A, for convenience of explanation of the structure of the rotation detection device, the housing and the substrate of the rotation detection device are not shown. Further, in FIG. 2B, for the convenience of description of the structure of the rotation detection device, the rotation detection device housing is shown in a transparent manner.

  As shown in FIG. 1, FIG. 2A, and FIG. 2B, the rotation detection device 1 is a device that detects a rotation state (for example, a rotation speed, a rotation direction, etc.) of a detection target (not shown). The rotation detection device 1 includes, for example, a covered cylindrical housing 2 and a shaft 3.

(1-1-1. Shaft and magnet)
The shaft 3 is supported so as to be rotatable with respect to the housing 2 about the axis AX as a rotation axis. One end of the shaft 3 on the one side in the axis AX direction is disposed in the housing 2, and the other end on the other side in the axis AX direction is connected to the detection target, for example, outside the housing 2.

  Here, for convenience of description of the structure of the rotation detection device 1, the vertical direction is determined as follows and used as appropriate. That is, one side of the axis AX direction, that is, the positive direction of the Z axis is defined as “up”, and the other side of the opposite axis AX direction, that is, the negative direction of the Z axis is defined as “down”. However, the directions such as up and down vary depending on the installation mode of the rotation detection device 1 and do not limit the positional relationship of each component of the rotation detection device 1.

  On the outer periphery of the shaft 3, magnets 4 a, 4 b, 4 c, 4 d (hereinafter, collectively referred to as “magnet 4” as appropriate) that are four permanent magnets are fixed by, for example, adhesion or a holder (not shown). Has been. That is, the shaft 3 corresponds to an example of a magnet support, and the axial center AX direction corresponds to an example of a rotation axis direction. Therefore, the magnets 4 a to 4 d rotate around the axis AX in conjunction with the rotation of the shaft 3. At this time, the magnets 4a, 4b, 4c, and 4d have their respective rotation locus circles R1, R2, R3, and R4 (hereinafter, collectively referred to as “rotation locus circle R” as appropriate) centered on the axis AX, and each of them. The rotation locus circles R1, R2, R3, and R4 rotate around the axis AX so that the radii (circumferences) are equal to each other. The magnets 4a to 4d are magnetized in the radial direction of each rotation locus circle R (hereinafter simply referred to as “radial direction” as appropriate), and the magnetic poles on the outer side in the radial direction are arranged in the circumferential direction of the rotation locus circle R ( Hereinafter, they are simply arranged so as to be alternately referred to as “circumferential direction”. For example, the magnets 4a, 4b, 4c, and 4d are arranged so that the magnetic poles on the outer side in the radial direction are N poles, S poles, N poles, and S poles. In FIG. 1, only the magnetic poles on the outer side in the radial direction of the magnet 4a are shown, and the magnetic poles of the magnets 4b and 4d are not shown. 2A and 3A to 3C, the magnetic poles of the magnets 4a to 4d are not shown.

  In the present embodiment, the lower end portion of the shaft 3 is formed in a columnar shape, and the other portions are formed in a quadrangular prism shape. The magnets 4a to 4d are flat magnets, and four magnets that form the outer periphery so as to be spaced apart at equal intervals (90 ° intervals) in the circumferential direction with respect to the outer periphery of the quadrangular columnar portion of the shaft 3. It is fixed to each side.

  Note that the number of magnets is not limited to four, but may be other numbers. In that case, what is necessary is just to change suitably also about the number, arrangement | positioning, etc. of the magnetic field detection part 5 and the magnetic members 6 and 7. FIG. The magnet 4 may be a magnet (such as an electromagnet) that is not a permanent magnet. Moreover, the shape of a shaft or a magnet is not limited to the above. For example, a magnet (multipolar magnet) in which a quadrangular columnar through-hole is formed may be fixed to the outer periphery of the quadrangular columnar portion of the shaft 3. Further, for example, the entire shaft may be formed in a cylindrical shape, and a ring magnet (multipolar magnet) or a plurality of arc-shaped magnets may be fixed to the outer periphery of the cylindrical shaft. Further, the magnet support is not limited to the shaft 3 but may be a member other than the shaft (for example, a hub connected to the shaft).

  The housing 2 includes a substrate 8, three magnetic field detectors 5 a, 5 b, 5 c (hereinafter collectively referred to as “magnetic field detector 5” as appropriate) and three first magnetic members 6 a, 6 b, 6 c (hereinafter referred to as “magnetic field detector 5”). As appropriate, collectively referred to as “first magnetic member 6”) and three second magnetic members 7a, 7b, 7c (hereinafter referred to as “second magnetic member 7” as appropriate) are accommodated.

(1-1-2. Substrate)
The substrate 8 is formed in an annular shape in which, for example, a through hole 81 through which the shaft 3 passes is formed, and is fixed to the lower end portion of the housing 2.

  The shape / fixed position of the substrate 8 is not limited to the above. For example, the substrate 8 may be fixed at a position other than the lower end of the housing 2. Further, for example, the substrate 8 may be fixed to a member fixed to the housing 2.

(1-1-3. Magnetic field detector)
The magnetic field detectors 5 a to 5 c include a magnetic element 51 that generates a large Barkhausen effect, and a coil 52 wound around the magnetic element 51.

  These magnetic field detectors 5a to 5c have their respective length directions (specifically, the length direction of the magnetic element 51) parallel to the tangential direction of the rotation locus circle R, and the magnets 4a to 4b in the radial direction (first It is fixed to the housing 2 via the substrate 8 so as to be able to oppose (via the magnetic member 6 and the second magnetic member 7). Specifically, the magnetic field detectors 5a to 5c are configured such that the shortest distance between one end in the length direction of the magnetic element 51 and the axis AX, and the other end in the length direction of the magnetic element 51 and the axis AX. It arrange | positions so that the shortest distance between may become equal. More specifically, in the magnetic field detectors 5a to 5c, the shortest distance between the central portion in the length direction of each magnetic element 51 and the axis AX is equal to each other, and the circumferential direction is, for example, equidistant (120 ° intervals). ) Are arranged around the shaft 3 so as to be separated from each other. That is, the magnetic field detectors 5 a to 5 c are arranged around the shaft 3 so as to have a substantially triangular shape when viewed from the direction of the axis AX.

  And the magnetic field detection parts 5a-5c can detect the magnetic field by the magnets 4a-4d.

  In addition, the arrangement | positioning shape of the magnetic field detection parts 5a-5c is not limited to triangular shape seeing from the axial center AX direction, Other shapes may be sufficient. Further, the number of the magnetic field detection units 5 is not limited to three, and may be another number. In that case, what is necessary is just to change suitably also about the number, arrangement | positioning, etc. of the magnet 4. FIG.

(1-1-3-1. Large Barkhausen effect and example of magnetic element)
Here, the “large Barkhausen effect” is a phenomenon in which the magnetization direction of the magnetic element 51 is rapidly reversed when the intensity of the applied external magnetic field exceeds a certain intensity, and is also referred to as a large Barkhausen jump.

  The magnetic element 51 is not particularly limited as long as it produces a large Barkhausen effect. For example, a wire-like magnetic element (for example, a composite magnetic wire, a Wiegand wire, an amorphous wire, etc.), a rod-like magnetic element A plate-like magnetic element or the like can be used. However, for convenience of explanation, a case where the magnetic element 51 is a composite magnetic wire will be described below.

(1-1-3-2. Magnetic properties of composite magnetic wire)
The composite magnetic wire has a magnetic property that its outer peripheral part changes its magnetization direction by applying a relatively small external magnetic field, but its central part has a magnetic characteristic that the magnetization direction does not change unless a relatively large external magnetic field is applied. An anisotropic composite magnetic material.

  That is, when a relatively large external magnetic field sufficient to reverse the magnetization direction of the center portion of the composite magnetic wire is applied in one direction parallel to the length direction of the composite magnetic wire, the magnetization direction of the center portion of the composite magnetic wire And the magnetization direction of the outer peripheral portion are aligned in the same direction. After that, when a relatively small external magnetic field that can reverse only the magnetization direction of the outer peripheral portion of the composite magnetic wire is applied in another direction opposite to the one direction, the magnetization direction of the center portion of the composite magnetic wire changes. Without reversing, only the magnetization direction of the outer periphery is reversed. As a result, the magnetic direction of the composite magnetic wire is different between the central portion and the outer peripheral portion, and this state is maintained even when the external magnetic field is removed.

  Here, for example, an external magnetic field is applied to the composite magnetic wire in a state where the central portion is magnetized in the one direction and the outer peripheral portion is magnetized in the other direction. At this time, the strength of the external magnetic field is initially reduced and then gradually increased. Then, when the intensity of the external magnetic field exceeds a certain intensity, a large Barkhausen effect occurs, and the magnetization direction of the outer peripheral portion of the composite magnetic wire is rapidly reversed from the other direction to the one direction. Then, a pulse signal that rises sharply in the positive direction, for example, is output from the coil wound around the composite magnetic wire by the electromotive force generated by the rapid reversal of the magnetization direction of the composite magnetic wire.

  Further, for example, an external magnetic field is applied in the other direction to the composite magnetic wire in which both the central portion and the outer peripheral portion are magnetized in the one direction. Also at this time, the strength of the external magnetic field is initially reduced and then gradually increased. Then, when the intensity of the external magnetic field exceeds a certain level, a large Barkhausen effect occurs, and the magnetization direction of the outer peripheral portion of the composite magnetic wire is rapidly reversed from the one direction to the other direction. Then, a pulse signal that rises sharply in the negative direction, for example, is output from the coil wound around the composite magnetic wire by the electromotive force generated by the rapid reversal of the magnetization direction of the composite magnetic wire.

(1-1-3-3. Outline of Operation of Magnetic Field Detection Unit)
In the magnetic field detectors 5a to 5c using the composite magnetic wire as described above as the magnetic element 51, when an external magnetic field is applied to the magnetic element 51 and the magnetization direction of the outer peripheral portion of the magnetic element 51 is reversed, the coil 52 A pulse signal is output.

  In the rotation detection device 1, the magnetic field corresponding to the external magnetic field applied to the magnetic element 51 is a magnetic field generated by two magnets 4 and 4 adjacent in the circumferential direction among the four magnets 4 a to 4 d, that is, the magnets 4 a and 4 d. The magnetic field by 4b, the magnetic field by magnets 4b and 4c, the magnetic field by magnets 4c and 4d, and the magnetic field by magnets 4d and 4a. These four magnetic fields are not large magnetic fields that can change the magnetization directions of both the central portion and the outer peripheral portion of the magnetic element 51, but can change only the magnetization directions of the outer peripheral portion of the magnetic element 51. The magnetic field.

  That is, when the magnets 4a to 4d rotate together with the shaft 3 in conjunction with the rotation of the detection target, the magnetic field (the direction of the magnetic field) applied to the magnetic element 51 of the magnetic field detectors 5a to 5c changes. As a result, in the magnetic field detectors 5 a to 5 c, the magnetization direction of the outer peripheral portion of the magnetic element 51 is reversed, and a pulse signal is output from the coil 52.

  Further, in the rotation detection device 1, as described above, the magnets 4a to 4d are arranged at intervals of 90 ° in the circumferential direction, and the magnetic field detection units 5a to 5c are arranged at intervals of 120 ° in the circumferential direction. . Therefore, the timing at which a pulse signal is output from each coil 52 of the magnetic field detectors 5a to 5c does not overlap while the shaft 3 rotates. The rotation state of the detection target can be detected by performing predetermined processing using pulse signals output at different timings from the coils 52 of the magnetic field detection units 5a to 5c.

(1-1-4. First magnetic member and second magnetic member)
The magnetic members 6a to 6c and 7a to 7c are fixed to the substrate 8 so as to be opposed to the magnets 4a to 4d and the magnetic field detectors 5a to 5c in the radial direction. That is, the magnetic members 6 a to 6 c and 7 a to 7 c are fixed to the housing 2 through the substrate 8. These magnetic members 6a to 6c and 7a to 7c are spaced apart from each other.

  The first magnetic members 6a to 6c are separated from each of the magnetic field detectors 5a to 5c, and cover the part facing the magnets 4a to 4d on one side in the longitudinal direction of each of the magnetic field detectors 5a to 5c. Has been placed. The second magnetic members 7a to 7c are spaced apart from the magnetic field detectors 5a to 5c, and cover the portions facing the magnets 4a to 4d on the other side in the length direction of the magnetic field detectors 5a to 5c. Have been placed.

  That is, the magnetic members 6 a to 6 c and 7 a to 7 c are divided into three sets of magnetic members 6 and 7, with the magnetic members 6 and 7 corresponding to the same single magnetic field detection unit 5 as one set. That is, the magnetic members 6a to 6c and 7a to 7c include a set of magnetic members 6a and 7a corresponding to the magnetic field detector 5a, a set of magnetic members 6b and 7b corresponding to the magnetic field detector 5b, and a magnetic field detector. It is divided into a set of magnetic members 6c and 7c corresponding to 5c. And magnetic member 6a, 7a, magnetic member 6b, 7b, and magnetic member 6c, 7c are arrange | positioned through the gap | interval in the longitudinal direction center part of the corresponding magnetic field detection part 5. FIG. Further, the magnetic members 6a and 7a, the magnetic members 6b and 7b, and the magnetic members 6c and 7c are the shortest distances between the axial center AX and the central portion in the length direction of the corresponding magnetic field detector 5 and the axial center AX. It is plane symmetric with the plane composed of lines passing through

  The magnetic members 6a and 7a can induce a magnetic field applied to the magnetic field detection unit 5a by the magnets 4a to 4d to form a predetermined magnetic path. Moreover, the magnetic members 6b and 7b can induce a magnetic field applied to the magnetic field detection unit 5b by the magnets 4a to 4d, and can form a predetermined magnetic path. Further, the magnetic members 6c and 7c can induce a magnetic field applied to the magnetic field detection unit 5c by the magnets 4a to 4d to form a predetermined magnetic path.

  In the present embodiment, the first magnetic members 6 a to 6 c include a first side plate portion 61 and a second side plate portion 62. Further, the second magnetic members 7 a to 7 c have a first side plate portion 71 and a second side plate portion 72. The first magnetic member 6 is formed with a first side plate portion 61 and a second side plate portion 62, for example, by forming a single flat plate into a desired shape by punching or the like and bending it by pressing or the like. The same applies to the second magnetic member 7.

  The first side plate portions 61 and 71 are erected in parallel with the axis AX direction. Each of the first side plate portions 61 and 71 is positioned so that one end of each of the first side plate portions 61 and 71 is located in the vicinity of the central portion in the length direction of the corresponding magnetic field detection unit 5 and can be opposed to the magnets 4a to 4d in the radial direction. Specifically, the first side plate portions 61 and 71 extend along the circumferential direction of a concentric circle having a larger radius than the rotation locus circle R, and are part of the circumference of the concentric circle when viewed from the axial center AX direction. Is formed in an arc shape along the line. Accordingly, the first side plate portions 61 and 71 of the magnetic members 6a and 7a, the magnetic members 6b and 7b, and the magnetic members 6c and 7c have a substantially circular shape when viewed from the axial center AX direction.

  The second side plate portions 62 and 72 are erected in parallel with the axial center AX direction. In addition, each of the second side plate portions 62 and 72 is connected at one end to the other end of each of the first side plate portions 61 and 71, and each other end is connected to the corresponding longitudinal end of the magnetic field detection unit 5. Is extended so as to protrude outward in the length direction. Specifically, the second side plate portions 62 and 72 are formed in a tapered shape toward the other end side. More specifically, the second side plates 62 and 72 are the second side plates of the first magnetic member 6a corresponding to one of the two magnetic field detectors 5 and 5 adjacent to each other in the circumferential direction. The part 62 and the second side plate part 72 of the second magnetic member 7a corresponding to the other magnetic field detection part 5 are extended so as to be parallel.

  For example, when it is possible to prevent a difficult change in the magnetization direction of the magnetic element 51 without using the magnetic field induction function (described later) of the magnetic members 6 and 7, the first magnetic member 6 and the second magnetic member 7 are used. Is not necessarily provided.

  Moreover, the shaping | molding method of the 1st magnetic member 6 is not limited above. For example, the first magnetic member 6 may be formed by connecting the first side plate portion 61 and the second side plate portion 62 made of different plate materials by welding or the like. Further, for example, the first magnetic member 6 may be integrally formed by casting. The same applies to the second magnetic member 7. Further, the first magnetic member is not limited to the shape or the like of the first magnetic members 6a to 6c described above, and is a portion facing at least the magnets 4a to 4d on one side in the length direction of the magnetic field detection unit 5. As long as it is a magnetic member that covers, other shapes may be used. Similarly, the second magnetic member is not limited to the shape or the like of the second magnetic members 7a to 7c described above, and faces at least the magnets 4a to 4d on the other side in the length direction of the magnetic field detection unit 5. Any other shape or the like may be used as long as it is a magnetic member that covers the portion.

(1-1-5. Positional relationship between magnet, magnetic member, and magnetic field detector)
As described above, in the present embodiment, the shaft 3 having the magnets 4 a to 4 d fixed to the outer periphery is disposed on the inner peripheral portion of the housing 2. And the magnetic field detection parts 5a-5c are arrange | positioned around the shaft 3 (magnets 4a-4d). Magnetic members 6a to 6c and 7a to 7c are arranged between the shaft 3 (magnets 4a to 4d) and the magnetic field detectors 5a to 5c in the radial direction. That is, the magnets 4a to 4d, the magnetic members 6a to 6c, 7a to 7c, and the magnetic field detectors 5a to 5c are arranged in such a manner that the magnets 4a to 4d, the magnetic members 6a to 6c, 7a to 7c, The magnetic field detectors 5a to 5c are arranged in this order.

  In addition, the structure of the rotation detection apparatus 1 demonstrated above is an example to the last, and a structure other than the above may be sufficient.

(1-2. Magnetic member induction function of magnetic member and operation of magnetic field detector)
Next, an example of the magnetic field induction function of the magnetic members 6 and 7 and the operation of the magnetic field detection unit 5 will be described with reference to FIGS. 3A, 3B, and 3C. Here, of the magnetic members 6a to 6c, 7a to 7c and the magnetic field detectors 5a to 5c, an example of the magnetic field induction function of the set of magnetic members 6a and 7a and the operation of the magnetic field detector 5a will be described as a representative. The magnetic field induction functions of the other magnetic members 6a and 7a and the operations of the other magnetic field detectors 5b and 5c are substantially the same. FIG. 3A illustrates an example of the magnetic field induction mode of the magnetic members 6a and 7a and the operation of the magnetic field detection unit 5a when the magnet 4a faces the first magnetic member 6a and the magnet 4d faces the second magnetic member 7a. It is a top view for doing. FIG. 3B is a plan view for explaining an example of the magnetic field induction mode of the magnetic members 6a and 7a and the operation of the magnetic field detector 5a when the magnet 4a faces the gap between the magnetic members 6a and 7a. FIG. 3C illustrates an example of the magnetic field induction mode of the magnetic members 6a and 7a and the operation of the magnetic field detection unit 5a when the magnet 4b faces the first magnetic member 6a and the magnet 4a faces the second magnetic member 7a. It is a top view for doing. In FIG. 3A to FIG. 3C, an example of the magnetic flux is conceptually illustrated by a thick arrow.

  As shown in FIG. 3A, when the magnet 4a faces the first magnetic member 6a and the magnet 4d faces the second magnetic member 7a, most of the magnetic flux from the magnet 4a toward the magnet 4d is from the magnet 4a. The first magnetic member 6a is entered.

  Most of the magnetic flux that has entered the first magnetic member 6a from the magnet 4a travels in the first side plate portion 61 of the first magnetic member 6a toward the second magnetic member 7a. At this time, since the magnetic members 6a and 7a are separated from each other via a gap, the magnetic flux that has traveled in the first side plate portion 61 toward the second magnetic member 7a is radially inward of the magnetic field detecting portion 5a. In FIG. 5, the magnetic field detector 5a enters a portion slightly on the one side with respect to the central portion in the length direction. This magnetic flux travels in the magnetic field detector 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches a portion on the other side slightly from the central portion. This magnetic flux leaves the magnetic field detection unit 5a and enters the second magnetic member 7a on the inner side in the radial direction of the magnetic field detection unit 5a. This magnetic flux travels toward the magnet 4d in the first side plate portion 71 of the second magnetic member 7a, and eventually reaches the magnet 4d.

  Further, part of the magnetic flux that has entered the first magnetic member 6a from the magnet 4a travels in the second side plate portion 62 of the first magnetic member 6a toward the other end side. A part of the magnetic flux enters a portion on one end side in the length direction of the magnetic field detector 5a. This magnetic flux travels in the magnetic field detector 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches the portion on the other side in the length direction. This magnetic flux leaves the magnetic field detector 5a and enters the second magnetic member 7a. This magnetic flux travels toward the magnet 4d in the second side plate portion 72 of the second magnetic member 7a, and eventually reaches the magnet 4d via the first side plate portion 71.

  As described above, when the magnet 4a faces the first magnetic member 6a and the magnet 4d faces the second magnetic member 7a, most of the magnetic flux from the magnet 4a toward the magnet 4d is caused by the magnetic members 6a and 7a. Be guided. Thereby, for example, a magnetic path (magnetic field) passing through the vicinity of the central portion in the length direction of the magnetic field detector 5a as shown by a thick solid arrow in FIG. 3A is formed. As a result, most of the magnetic flux from the magnet 4a toward the magnet 4d is applied to the central portion in the length direction of the magnetic field detector 5a, so that the magnetic flux density at the central portion in the length direction of the magnetic field detector 5a is the length of the magnetic flux. It becomes higher than the magnetic flux density at one end and the other end in the direction.

  Further, for example, a magnetic field directed from one end side in the length direction of the magnetic field detection unit 5a to the other end side as shown by a thick broken line arrow in FIG. 3A is also formed. This magnetic field is applied not only to the central portion in the length direction of the magnetic element 51 of the magnetic field detector 5a but also to one end portion and the other end portion in the length direction. However, since most of the magnetic flux from the magnet 4a toward the magnet 4d passes through the magnetic path indicated by the thick solid arrow in FIG. 3A, the strength of the magnetic field indicated by the thick broken arrow in FIG. 3A is the thick solid line in FIG. 3A. It is smaller than the magnetic field strength indicated by the arrow. 3A is applied to the magnetic field detection unit 5a, the magnetic field density at the center in the length direction of the magnetic field detection unit 5a is reduced at one end or the other end in the length direction. While the state higher than the magnetic flux density is maintained, the magnetic flux density of the magnetic field detector 5a increases as a whole.

  By applying the magnetic field as described above to the magnetic field detection unit 5a, the magnetic element 51 of the magnetic field detection unit 5a is in the direction indicated by the block arrow in FIG. It is magnetized in the direction facing the part. Therefore, when the previous magnetization direction of the magnetic element 51 of the magnetic field detection unit 5a is the direction from the other end in the length direction of the magnetic element 51 to one end, the magnetization direction of the outer peripheral portion of the magnetic element 51 is For example, a pulse signal in the positive direction is output from the coil 52 of the magnetic field detector 5a.

  Subsequently, as shown in FIG. 3B, when the shaft 3 rotates counterclockwise, for example, and the magnet 4a faces the gap between the magnetic members 6a and 7a, most of the magnetic flux from the magnet 4a to the magnet 4b. Enters the first magnetic member 6a from the magnet 4a. Most of the magnetic flux that has entered the first magnetic member 6a from the magnet 4a proceeds toward the magnet 4b in the first side plate portion 61 of the first magnetic member 6a, and eventually the second side plate portion of the first magnetic member 6a. It enters 62 and advances in the second side plate portion 62 toward the other end side. At this time, since the first magnetic member 6a and the second magnetic member 7b adjacent to the first magnetic member 6a in the circumferential direction are separated from each other, most of the magnetic flux that has traveled in the first magnetic member 6a. Does not enter the second magnetic member 7b. However, a part of the magnetic flux that has traveled through the first magnetic member 6a is separated from the other end of the second side plate 62 of the first magnetic member 6a and the other end of the second side plate 72 of the second magnetic member 7b. For example, a magnetic path as shown by a thick broken line arrow in FIG. 3B is formed. Thereby, it can suppress that magnetic flux is emitted (scattered) outward. Note that most of the magnetic flux that has entered the other end of the second side plate portion 72 of the second magnetic member 7b travels toward the magnet 4b in the second side plate portion 72 of the second magnetic member 7b, and eventually the first. Since the magnet 4b is reached via the side plate 71, the magnetic field detector 5b is hardly applied.

  When the magnet 4a faces the gap between the magnetic members 6a and 7a, most of the magnetic flux from the magnet 4a to the magnet 4d enters the second magnetic member 7a from the magnet 4a. Most of the magnetic flux that has entered the second magnetic member 7a from the magnet 4a travels toward the magnet 4d in the first side plate 71 of the second magnetic member 7a, and eventually the second side plate of the second magnetic member 7a. 72, the second side plate 72 is advanced toward the other end side. At this time, since the second magnetic member 7a and the first magnetic member 6c adjacent to the second magnetic member 7a in the circumferential direction are separated from each other, most of the magnetic flux that has traveled in the second magnetic member 7a. Does not enter the first magnetic member 6c. However, a part of the magnetic flux that has traveled through the second magnetic member 7a is detached from the other end of the second side plate 72 of the second magnetic member 7a and the other end of the second side plate 62 of the first magnetic member 6c. For example, a magnetic path as shown by a thick broken line arrow in FIG. 3B is formed. Thereby, it can suppress that magnetic flux is emitted (scattered) outward. Note that most of the magnetic flux that has entered the other end portion of the first side plate portion 62 of the first magnetic member 6c travels toward the magnet 4d in the second side plate portion 62 of the first magnetic member 6c. Since it reaches the magnet 4d via the side plate portion 61, it is hardly applied to the magnetic field detecting portion 5c.

  Further, when the magnet 4a is opposed to the gap between the magnetic members 6a and 7a, the magnetic flux traveling through the first magnetic member 6a and the magnetic flux traveling through the second magnetic member 7a are the axis AX and the magnetic field detection. The surface is symmetrical with respect to a plane composed of a line passing through the central portion in the length direction of the portion 5a and a point having the shortest distance on the axis AX. For this reason, in the space surrounded by the magnetic members 6a and 7a around the magnetic field detection unit 5a, the magnetic field from the magnet 4a to the magnet 4b and the magnetic field from the magnet 4a to the magnet 4d cancel each other, and the magnetic field is almost equal. 0.

  As described above, when the magnet 4a faces the gap between the magnetic members 6a and 7a, the magnetic field from the magnet 4a toward the magnets 4b and 4d is avoided by the magnetic members 6a and 7a. Be guided. As a result, most of the magnetic flux from the magnet 4a toward the magnets 4b and 4d does not enter the magnetic field detector 5a. Therefore, the magnetization direction of the outer periphery of the magnetic element 51 of the magnetic field detector 5a does not change. That is, the direction indicated by the block arrow in FIG. 3B is the same as the direction indicated by the block arrow in FIG. 3A, which means that the magnetization direction of the magnetic element 51 of the magnetic field detector 5a has not changed. Therefore, in this case, no pulse signal is output from the coil 52 of the magnetic field detector 5a.

  Subsequently, as shown in FIG. 3C, when the shaft 3 further rotates, for example, counterclockwise, the magnet 4b faces the first magnetic member 6a, and the magnet 4a faces the second magnetic member 7a, the magnet A magnetic flux directed from 4a to the magnet 4b is induced by the magnetic members 6a and 7a, and a magnetic field having a direction opposite to the direction of the magnetic field described with reference to FIG. 3A is formed. That is, for example, a magnetic path (magnetic field) passing through the vicinity of the central portion in the length direction of the magnetic field detection unit 5a as shown by a thick solid arrow in FIG. 3C is formed. As a result, most of the magnetic flux from the magnet 4a toward the magnet 4b is applied to the central portion in the length direction of the magnetic field detector 5a, so that the magnetic flux density at the central portion in the length direction of the magnetic field detector 5a It becomes higher than the magnetic flux density at one end and the other end in the direction. Further, for example, a magnetic field from the other end in the length direction of the magnetic field detector 5a toward the one end as shown by a thick broken line arrow in FIG. 3C is also formed. This magnetic field is applied not only to the central portion in the length direction of the magnetic element 51 of the magnetic field detector 5a but also to one end portion and the other end portion in the length direction. However, since most of the magnetic flux from the magnet 4a toward the magnet 4b passes through the magnetic path indicated by the thick solid arrow in FIG. 3C, the strength of the magnetic field indicated by the thick broken arrow in FIG. 3C is the thick solid line in FIG. 3C. It is smaller than the magnetic field strength indicated by the arrow. Therefore, when the magnetic field indicated by the thick broken line arrow in FIG. 3C is applied to the magnetic field detection unit 5a, the magnetic field density at the center in the length direction of the magnetic field detection unit 5a is reduced at one end or the other end in the length direction. While the state higher than the magnetic flux density is maintained, the magnetic flux density of the magnetic field detector 5a increases as a whole.

  When the magnetic field as described above is applied to the magnetic field detection unit 5a, the outer peripheral portion of the magnetic element 51 of the magnetic field detection unit 5a is in the direction indicated by the block arrow in FIG. 3C, that is, the other end in the length direction of the magnetic element 51. Is magnetized in a direction from one part to one end. Therefore, when the magnetization direction of the tip of the outer periphery of the magnetic element 51 of the magnetic field detector 5a is the direction from one end in the length direction of the magnetic element 51 to the other end, The magnetization direction is reversed, and, for example, a pulse signal in the negative direction is output from the coil 52 of the magnetic field detector 5a.

  Note that the magnetic field induction function of the magnetic members 6 and 7 and the operation of the magnetic field detection unit 5 described above are merely examples, and modes other than those described above may be used.

(1-3. Examples of effects according to this embodiment)
In the present embodiment described above, the magnetic field detectors 5a to 5c are fixed to the housing 2 such that their length directions are parallel to the tangential direction of the rotation locus circle R and can face the magnets 4a to 4d in the radial direction. Has been. By arranging the magnetic field detectors 5a to 5c in such a manner that the length direction of the magnetic field detectors 5a to 5c is parallel to the tangential direction of the rotation locus circle R, for example, the length direction of the magnetic field detectors 5a to 5c is the axial center AX direction. Compared with the case where they are arranged in parallel, the dimension of the rotation detector 1 in the direction of the axis AX can be reduced. Further, the magnetic field detectors 5a to 5c are arranged to be able to face the magnets 4a to 4d in the radial direction, so that the magnetic field detectors 5a to 5c are arranged to be able to face the magnets 4a to 4d in the axial center AX direction, for example. Compared to the case, the dimension of the rotation detecting device 1 in the axis AX direction can be reduced. Therefore, the axial dimension of the rotation detection device 1 can be reduced.

  In the present embodiment, the first magnetic member 6 that covers one side in the length direction of the magnetic field detector 5 and the second magnetic member 7 that covers the other side in the length direction of the magnetic field detector 5 correspond to the corresponding magnetic field detection. In the case where the magnetic member 51 is disposed through a gap in the central portion in the length direction of the portion 5, the magnetic field induction function of the magnetic members 6 and 7 prevents an unpredictable change in the magnetization direction of the magnetic element 51, thereby Detection accuracy can be increased.

  In the present embodiment, the magnets 4a to 4d, the magnetic members 6a to 6c, 7a to 7c, and the magnetic field detectors 5a to 5c are directed from the inner side to the outer side in the radial direction, and the magnets 4a to 4d and the magnetic members 6a to 6c. , 7a to 7c and magnetic field detectors 5a to 5c are arranged in this order, the following effects are obtained. That is, since the shaft 3 can be used as the magnet support body with the above configuration, the magnet support structure can be simplified. Further, by arranging the rotating shaft 3 at the center and arranging the magnetic members 6a to 6c, 7a to 7c and the magnetic field detectors 5a to 5c on the outer peripheral side, it is possible to reduce the influence of the magnetic flux on the peripheral components.

  Further, in the present embodiment, the magnetic members 6a to 6c and 7a to 7c are extended so as to be opposed to the magnets 4a to 4d in the radial direction with one end positioned near the center in the length direction of the magnetic field detectors 5a to 5c. First side plate portions 61, 71 having one end connected to the first side plate portions 61, 71 and the other end protruding outward in the length direction from the length direction end portions of the magnetic field detection portions 5a to 5c. In the case of having the extended second side plate portions 62 and 72, the following effects are obtained. That is, when the first side plate portions 61 and 71 are opposed to the magnets 4a to 4d, the magnetic members 6a to 6c and 7a to 7c can strengthen the magnetic field applied to the magnetic field detection units 5a to 5c, and the magnetic members 6 and 7 are used. A relatively strong magnetic field can be applied to the central portion in the length direction of the magnetic field detectors 5a to 5c due to the gap therebetween. Further, the second side plate portions 62 and 72 protrude outward in the length direction from the end portions in the length direction of the magnetic field detection portions 5a to 5c, so that the entire length direction of the magnetic field detection portions 5a to 5c is increased. A relatively weak magnetic field in the same direction as the strong magnetic field can be applied. Therefore, it is possible to improve the stability of generating the Barkhausen effect at a desired timing in the magnetic element 51.

  Further, in the present embodiment, when the second side plate portions 62 and 72 are tapered toward the other end side, the following effects are obtained. That is, with the above configuration, the amount of magnetic flux traveling from the first side plate portions 61 and 71 to the second side plate portions 62 and 72 is reduced, and the magnetic fields applied to both end portions in the length direction of the magnetic field detection units 5a to 5c. It can prevent becoming larger than the central part in the length direction. Therefore, the distribution of the magnetic flux density applied to the magnetic element 51 can be optimized, and the stability of generating the Barkhausen effect at a desired timing in the magnetic element 51 can be further improved.

(1-4. Modifications etc.)
The first embodiment has been described in detail above. However, the scope of the technical idea described in the claims is not limited to the first embodiment described here. It is obvious that a person having ordinary knowledge in the technical field to which the first embodiment belongs can make various changes, corrections, combinations, and the like within the scope of the technical idea. Accordingly, the technology after these changes, corrections, combinations, and the like are naturally within the scope of the technical idea. Hereinafter, such modifications will be described in order.

(1-4-1. Another Example of Configuration of Magnetic Member [Part 1])
In this modified example, the first magnetic member and the second magnetic member include a third side plate portion that covers an end portion in the length direction of the magnetic field detection unit 5 in addition to the first side plate portion and the second side plate portion, and a magnetic field detection unit. It is an example in the case of providing the 4th side board part which covers the outer side of 5 radial directions.

(1-4-1-1. Configuration of Rotation Detection Device)
Hereinafter, an example of the configuration of the rotation detection device 1A according to the present modification will be described with reference to FIGS. 4A, 4B, and 4C. 4A to 4C, the housing 2 and the substrate 8 are not shown.

  As shown in FIGS. 4A to 4C, in the rotation detection device 1A, the configuration different from the rotation detection device 1 according to the embodiment is a first magnetic member, a second magnetic member, and the like, and the shaft 3 and magnets 4a to 4d. The magnetic field detectors 5a to 5c are the same as those in the above embodiment.

  The first magnetic members 6Aa, 6Ab, 6Ac according to this modification (hereinafter collectively referred to as “first magnetic member 6A” as appropriate) are magnets 4a-4d on one side in the length direction of each of the magnetic field detectors 5a-5c. The housing 2 is fixed to the housing 2 through the substrate 8 so as to cover a portion facing the surface. The second magnetic members 7Aa, 7Ab, and 7Ac (hereinafter collectively referred to as “second magnetic member 7A” as appropriate) oppose the magnets 4a to 4d on the other side in the length direction of the magnetic field detectors 5a to 5c. It is fixed to the housing 2 via the substrate 8 so as to cover the part and the like. The magnetic members 6Aa, 7Aa, the magnetic members 6Ab, 7Ab, and the magnetic members 6Ac, 7Ac are arranged with a gap at the center in the length direction of the corresponding magnetic field detector 5, and the axis AX and the corresponding magnetic field The plane is symmetrical with a plane composed of a line passing through a central portion in the length direction of the detection unit 5 and a point having the shortest distance on the axis AX as a plane of symmetry.

  In the present modification, the first magnetic members 6Aa to 6Ac include a first side plate portion 61, a second side plate portion 62A, a third side plate portion 63, and a fourth side plate portion 64 that are the same as in the above embodiment. Moreover, 2nd magnetic member 7Aa-7Ac has the 1st side board part 71 similar to the said embodiment, 2nd side board part 72A, the 3rd side board part 73, and the 4th side board part 74. As shown in FIG. The first magnetic member 6A is formed, for example, by forming a single flat plate into a desired shape by punching or the like, and bending it by pressing or the like, whereby the first side plate portion 61, the second side plate portion 62A, the third side plate portion 63, And the 4th side board part 64 is formed. The same applies to the second magnetic member 7A.

  The second side plate portions 62A and 72A are basically the same as the second side plate portions 62 and 72 described above, but have a smaller dimension in the extending direction than each of the second side plate portions 62 and 72, and each of the other side plate portions 62A and 72A. The point which is not tapered toward the end side is different.

  The third side plate parts 63 and 73 are erected in parallel with the axial center AX direction. Further, the third side plate portions 63 and 73 are connected to the other end of each of the second side plate portions 62A and 72A, and outward in the length direction from the corresponding length direction end portions of the magnetic field detection units 5. Are extended along the width direction of the magnetic field detector 5.

  The fourth side plate portions 64 and 74 are erected in parallel with the axis AX direction. In addition, each of the fourth side plate portions 64 and 74 has one end connected to the other end of each of the third side plate portions 63 and 73, and the length of the magnetic field detection unit 5 outside the corresponding magnetic field detection unit 5 in the radial direction. It extends along the direction.

  The shapes and the like of the magnetic members 6A and 7A described above are merely examples, and shapes other than those described above may be used. Further, the molding method of the first magnetic member 6A is not limited to the above. For example, even if the first magnetic member 6A is formed by connecting the first side plate portion 61, the second side plate portion 62A, the third side plate portion 63, and the fourth side plate portion 64 made of different plate materials by welding or the like. Good. Further, for example, the first magnetic member 6A may be integrally formed by casting. The same applies to the second magnetic member 7A. In the above description, the first magnetic member 6 </ b> A is configured to include both the third side plate portion 63 and the fourth side plate portion 64, but may be configured to include only the third side plate portion 63. The same applies to the second magnetic member 7A.

(1-4-1-2. Magnetic field induction function of magnetic member and operation of magnetic field detector)
Next, an example of the magnetic field induction function of the magnetic members 6A and 7A and the operation of the magnetic field detection unit 5 will be described with reference to FIG. Here, as in the above embodiment, an example of the magnetic field induction function of one set of magnetic members 6Aa and 7Aa and the operation of the magnetic field detection unit 5a will be described as a representative. However, the magnetic field induction function of other sets of magnetic members 6Aa and 7Aa. The operations of the other magnetic field detectors 5b and 5c are substantially the same.

  As shown in FIG. 5, when the magnet 4a faces the first magnetic member 6Aa and the magnet 4d faces the second magnetic member 7Aa, the first side plate portion 61 and the second side plate portion 62A of the first magnetic member 6Aa. The magnetic field induction functions of the first side plate portion 71 and the second side plate portion 72A of the second magnetic member 7Aa have been described with reference to FIG. 3A, and the first side plate portion 61 and the second side plate portion of the first magnetic member 6a. 62 and the magnetic field induction function of the first side plate portion 71 and the second side plate portion 72 of the second magnetic member 7a. Therefore, here, mainly an example of the magnetic field induction function of the third side plate portion 63 and the fourth side plate portion 64 of the first magnetic member 6Aa and the third side plate portion 73 and the fourth side plate portion 74 of the second magnetic member 7Aa. Will be described.

  That is, a part of the magnetic flux that has entered the first magnetic member 6Aa from the magnet 4a proceeds in the third side plate portion 63 of the first magnetic member 6Aa toward the fourth side plate portion 64. A part of the magnetic flux enters a portion on one end side in the length direction of the magnetic field detector 5a. This magnetic flux travels in the magnetic field detector 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches the portion on the other side in the length direction. This magnetic flux leaves the magnetic field detector 5a and enters the second magnetic member 7Aa. The magnetic flux sequentially proceeds through the third side plate portion 73, the second side plate portion 72A, and the first side plate portion 71 of the second magnetic member 7Aa, and eventually reaches the magnet 4d.

  Further, since the magnetic members 6Aa and 7Aa are separated by a gap, most of the magnetic flux that has traveled toward the other end side in the fourth side plate portion 64 of the first magnetic member 6Aa is the magnetic field detecting portion 5a. In the outer side in the radial direction, the magnetic field detection unit 5a enters a portion slightly on the one side with respect to the central portion in the length direction. This magnetic flux travels in the magnetic field detector 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches a portion on the other side slightly from the central portion. This magnetic flux leaves the magnetic field detection unit 5a and enters the second magnetic member 7Aa outside the magnetic field detection unit 5a in the radial direction. The magnetic flux sequentially proceeds through the fourth side plate portion 74, the third side plate portion 73, the second side plate portion 72A, and the first side plate portion 71 of the second magnetic member 7Aa, and eventually reaches the magnet 4d.

  As described above, when the magnet 4a faces the first magnetic member 6Aa and the magnet 4d faces the second magnetic member 7Aa, most of the magnetic flux from the magnet 4a toward the magnet 4d is caused by the magnetic members 6Aa and 7Aa. Be guided. Thereby, for example, a relatively strong magnetic path (magnetic field) passing through the vicinity of the central portion in the length direction of the magnetic field detector 5a as shown by the thick solid arrow in FIG. 5 is formed. Further, for example, a relatively weak magnetic field from the one end side in the length direction of the magnetic field detection unit 5a to the other end side as shown by a thick broken line arrow in FIG. 5 is also formed.

  By applying the magnetic field as described above to the magnetic field detection unit 5a, the outer peripheral portion of the magnetic element 51 of the magnetic field detection unit 5a is magnetized in the direction indicated by the block arrow in FIG. Therefore, when the previous magnetization direction of the magnetic element 51 is opposite to the block arrow, the magnetization direction of the magnetic element 51 is reversed, and a pulse signal in the positive direction is output from the coil 52 of the magnetic field detector 5a. Is done.

  Note that the magnetic field induction function of the magnetic members 6A and 7A and the operation of the magnetic field detection unit 5 described above are merely examples, and modes other than the above may be used.

(1-4-1-3. Examples of effects of this modification)
Also in this modified example described above, the same effect as in the above embodiment can be obtained. Furthermore, in this modification, the magnetic members 6A and 7A have the third side plate portions 63 and 73 and the fourth side plate portions 64 and 74, so that the magnetic field applied to the magnetic field detection unit 5 can be made stronger. Stability and efficiency can be improved. In addition, since the magnetic members 6A and 7A have the third side plates 63 and 73, the influence of the dimensional tolerance and the position tolerance in the length direction of the magnetic field detector 5 can be reduced, and the fourth side plates 64 and 74 are provided. Thereby, the influence of the dimensional tolerance and the position tolerance in the radial direction of the magnetic field detector 5 can be reduced. Furthermore, since the magnetic members 6A and 7A have the third side plate portions 63 and 73 and the fourth side plate portions 64 and 74, the influence of a disturbance magnetic field from the outside in the radial direction can be reduced.

(1-4-2. Another Example of Configuration of Magnetic Member [Part 2])
This modification is an example in which the first magnetic member and the second magnetic member include a first flat plate portion that covers the upper side of the magnetic field detection unit 5 in addition to the first side plate portion and the second side plate portion.

(1-4-2-1. Configuration of Rotation Detection Device)
Hereinafter, an example of the configuration of the rotation detection device 1B according to this modification will be described with reference to FIGS. 6A, 6B, and 6C. In FIG. 6A, for convenience of description of the structure of the rotation detection device 1, a set of first magnetic member and second magnetic member corresponding to the magnetic field detector 5a is not shown. Moreover, illustration of the housing 2 and the board | substrate 8 is abbreviate | omitted in FIG. 6A-FIG. 6C.

  As shown in FIGS. 6A to 6C, the rotation detection device 1B is different from the rotation detection device 1 according to the above embodiment in the first magnetic member, the second magnetic member, and the like, and the shaft 3 and the magnets 4a to 4d. The magnetic field detectors 5a to 5c are the same as those in the above embodiment.

  The first magnetic members 6Ba, 6Bb, 6Bc (hereinafter collectively referred to as “first magnetic member 6B” as appropriate) according to this modification are magnets 4a-4d on one side in the length direction of each of the magnetic field detectors 5a-5c. The housing 2 is fixed to the housing 2 through the substrate 8 so as to cover a portion facing the surface. Further, the second magnetic members 7Ba, 7Bb, 7Bc (hereinafter collectively referred to as “second magnetic member 7B” as appropriate) are opposed to the magnets 4a-4d on the other side in the longitudinal direction of each of the magnetic field detectors 5a-5c. It is fixed to the housing 2 via the substrate 8 so as to cover the part and the like. The magnetic members 6Ba and 7Ba, the magnetic members 6Bb and 7Bb, and the magnetic members 6Bc and 7Bc are arranged with a gap at the central portion in the length direction of the corresponding magnetic field detector 5, and the axis AX and the corresponding magnetic field The plane is symmetrical with a plane composed of a line passing through a central portion in the length direction of the detection unit 5 and a point having the shortest distance on the axis AX as a plane of symmetry.

  In the present modification, the first magnetic members 6Ba to 6Bc include a first side plate portion 61B, a second side plate portion 62B, and a first flat plate portion 65. The second magnetic members 7Ba to 7Bc include a first side plate portion 71B, a second side plate portion 72B, and a first flat plate portion 75. The first magnetic member 6B is formed, for example, by forming a single flat plate into a desired shape by punching or the like, and bending it by pressing or the like, whereby the first side plate portion 61B, the second side plate portion 62B, and the first flat plate portion 65 are formed. Is formed. For this reason, for example, the first side plate portion 61B is connected to each of the second side plate portion 62B and the first flat plate portion 65, but the second side plate portion 62B and the first flat plate portion 65 are not connected. It is connected (including the case where a minute gap is vacant) by being folded. The same applies to the second magnetic member 7B.

  The first side plate portions 61B and 72B are basically the same as the first side plate portions 61 and 72 described above, but extend along the tangential direction of a concentric circle having a radius larger than the rotation locus circle R, and the axis AX The difference is that it is formed in a straight line when viewed from the direction. Therefore, each of the magnetic members 6Ba and 7Ba, the magnetic members 6Bb and 7Bb, and the first side plate portions 61B and 72B of the magnetic members 6Bc and 7Bc has a substantially hexagonal shape when viewed from the axial center AX direction.

  The second side plate portions 62B and 72B are basically the same as the second side plate portions 62 and 72 described above, except that the second side plate portions 62B and 72B are not tapered toward the other end side.

  The first flat plate portions 65 and 75 are connected to the first side plate portions 61B and 71B and the second side plate portions 62B and 72B, respectively, and cover the upper side of the corresponding magnetic field detection unit 5 in the axial center AX direction. It extends vertically.

  Note that the shapes and the like of the magnetic members 6B and 7B described above are merely examples, and shapes other than those described above may be used. Moreover, the shaping | molding method of the 1st magnetic member 6B is not limited above. For example, the first magnetic member 6B may be formed by connecting the first side plate portion 61B, the second side plate portion 62B, and the first flat plate portion 65 made of different plate materials by welding or the like. Further, for example, the first magnetic member 6B may be integrally formed by casting. The same applies to the second magnetic member 7B.

(1-4-2-2. Magnetic field induction function of magnetic member and operation of magnetic field detector)
Next, an example of the magnetic field induction function of the magnetic members 6B and 7B and the operation of the magnetic field detection unit 5 will be described with reference to FIGS. 7A and 7B.

  As shown in FIGS. 7A and 7B, when the magnet 4a faces the first magnetic member 6Ba and the magnet 4d faces the second magnetic member 7Ba, the first side plate portion 61B and the second side plate portion 61B of the first magnetic member 6Ba The magnetic field induction functions of the side plate 62B and the first side plate 71B and the second side plate 72B of the second magnetic member 7Ba are substantially the same as those described with reference to FIG. 3A. Therefore, here, an example of the magnetic field induction function of the first flat plate portion 65 of the first magnetic member 6Ba and the first flat plate portion 75 of the second magnetic member 7Ba will be mainly described.

  That is, part of the magnetic flux that has entered the first magnetic member 6Ba from the magnet 4a also enters the first flat plate portion 65 that is connected to the first side plate portion 61B. Most of the magnetic flux travels in the first flat plate portion 65 toward the second magnetic member 7Ba. At this time, since the magnetic members 6Ba and 7Ba are separated by a gap, the magnetic flux that has traveled toward the second magnetic member 7Ba in the first flat plate portion 65 is on the upper side of the magnetic field detector 5a. The magnetic field detector 5a enters a portion slightly on the one side with respect to the central portion in the length direction. This magnetic flux travels in the magnetic field detector 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches a portion on the other side slightly from the central portion. This magnetic flux leaves the magnetic field detection unit 5a and enters the second magnetic member 7Ba on the upper side of the magnetic field detection unit 5a. This magnetic flux travels toward the magnet 4d in the first flat plate portion 75 of the second magnetic member 7Ba, and eventually reaches the magnet 4d via the first side plate portion 71B.

  Further, part of the magnetic flux that has entered the first flat plate portion 65 of the first magnetic member 6Ba travels in the first flat plate portion 65 toward the side opposite to the second magnetic member 7Ba side. This magnetic flux enters a portion on one end side in the length direction of the magnetic field detection unit 5a on the upper side of the magnetic field detection unit 5a. This magnetic flux travels in the magnetic field detector 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches the portion on the other side in the length direction. This magnetic flux leaves the magnetic field detector 5a and enters the second magnetic member 7Ba. This magnetic flux travels toward the magnet 4d in the first flat plate portion 75 of the second magnetic member 7Ba, and eventually reaches the magnet 4d via the first side plate portion 71B.

  As described above, when the magnet 4a faces the first magnetic member 6Ba and the magnet 4d faces the second magnetic member 7Ba, most of the magnetic flux from the magnet 4a toward the magnet 4d is caused by the magnetic members 6Ba and 7Ba. Be guided. Thereby, for example, a relatively strong magnetic path (magnetic field) passing through the vicinity of the central portion in the length direction of the magnetic field detector 5a as shown by a thick solid arrow in FIGS. 7A and 7B is formed. Further, for example, a relatively weak magnetic field is formed from the one end side in the length direction of the magnetic field detection unit 5a to the other end side as indicated by a thick broken line arrow in FIGS. 7A and 7B.

  By applying the magnetic field as described above to the magnetic field detector 5a, the outer peripheral portion of the magnetic element 51 of the magnetic field detector 5a is magnetized in the direction indicated by the block arrows in FIGS. 7A and 7B. Therefore, when the previous magnetization direction of the magnetic element 51 is opposite to the block arrow, the magnetization direction of the magnetic element 51 is reversed, and a pulse signal in the positive direction is output from the coil 52 of the magnetic field detector 5a. Is done.

  Note that the magnetic field induction function of the magnetic members 6B and 7B and the operation of the magnetic field detection unit 5 described above are merely examples, and modes other than the above may be used.

(1-4-2-3. Examples of effects of this modification)
Also in this modified example described above, the same effect as in the above embodiment can be obtained. Furthermore, in this modification, the magnetic members 6B and 7B have the first flat plate portions 65 and 75, so that the magnetic field applied to the magnetic field detection unit 5 can be made stronger, and the magnetic stability and efficiency are improved. it can. Furthermore, the influence of the disturbance magnetic field from the upper part can be reduced.

  In the present modification, the first side plate portions 61B and 71B of the magnetic members 6B and 7B are arranged in a substantially hexagonal shape. Accordingly, the distance between the first side plate portions 61B and 71B and the rotation locus circle R is closest in the central portion of the first side plate portions 61B and 71B, and becomes farther as the gap portion between the first side plate portions 61B and 71B approaches. Thereby, for example, compared with the case where the first side plate portion is arranged in a circular shape as in the above-described embodiment, it is caused by the magnetic attractive force acting between the magnets 4a to 4d and the first side plate portions 61B and 71B. The cogging torque of the shaft 3 can be reduced.

(1-4-3. Another example of configuration of magnetic member [part 3])
In this modification, the first magnetic member and the second magnetic member have a first flat plate portion that covers the upper side of the magnetic field detection unit 5 in addition to the first side plate portion and the second side plate portion, and a lower side of the magnetic field detection unit 5. It is an example in the case of providing the 2nd flat plate part which covers.

(1-4-3-1. Configuration of rotation detection device)
Hereinafter, an example of the configuration of the rotation detection device 1C according to the present modification will be described with reference to FIGS. 8A, 8B, and 8C. In FIG. 8A, for convenience of description of the structure of the rotation detection device 1, a set of first magnetic member and second magnetic member corresponding to the magnetic field detection unit 5 a is not shown. 8A to 8C, the housing 2 and the substrate are not shown.

  As shown in FIGS. 8A to 8C, in the rotation detection device 1C, the configuration different from the rotation detection device 1 according to the embodiment is a first magnetic member, a second magnetic member, and the like, and the shaft 3 and magnets 4a to 4d. The magnetic field detectors 5a to 5c are the same as those in the above embodiment.

  The first magnetic members 6Ca, 6Cb, 6Cc (hereinafter collectively referred to as “first magnetic member 6C” as appropriate) according to this modification are magnets 4a-4d on one side in the length direction of each of the magnetic field detectors 5a-5c. It is being fixed to the housing 2 so that the part etc. which oppose may be covered. The second magnetic members 7Ca, 7Cb, 7Cc (hereinafter collectively referred to as “second magnetic member 7C” as appropriate) are opposed to the magnets 4a-4d on the other side in the longitudinal direction of each of the magnetic field detectors 5a-5c. It is being fixed to the housing 2 so that a part etc. may be covered. The magnetic members 6Ca and 7Ca, the magnetic members 6Cb and 7Cb, and the magnetic members 6Cc and 7Cc are arranged with a gap at the central portion in the length direction of the corresponding magnetic field detector 5, and the axis AX and the corresponding magnetic field The plane is symmetrical with a plane composed of a line passing through a central portion in the length direction of the detection unit 5 and a point having the shortest distance on the axis AX as a plane of symmetry.

  In the present modification, for example, an annular substrate (not shown) is disposed on the outside in the radial direction of the magnetic field detectors 5a to 5c and the magnetic members 6Ca to 6Cc and 7Ca to 7Cc, for example. Alternatively, instead of installing a substrate, a circuit press part may be integrally formed in a mold resin for molding each component of the rotation detection device 1.

  In the present modification, the first magnetic members 6Ca to 6Cc include the first side plate portion 61B, the second side plate portion 62B, the first flat plate portion 65, and the second flat plate portion 67, which are the same as those of the rotation detection device 1B. . Moreover, 2nd magnetic member 7Ba-7Bc has the 1st side board part 71B similar to the said rotation detection apparatus 1B, the 2nd side board part 72B, the 1st flat plate part 75, and the 2nd flat plate part 77. FIG. The first magnetic member 6C is formed, for example, by forming a single flat plate into a desired shape by punching or the like, and bending it by pressing or the like, whereby the first side plate portion 61B, the second side plate portion 62B, the first flat plate portion 65, And the 2nd flat plate part 67 is formed. Therefore, for example, the first side plate portion 61B is connected to each of the second side plate portion 62B, the first flat plate portion 65, and the second flat plate portion 67, but the second side plate portion 62B and the first flat plate portion 65 are connected. And the 2nd side board part 62B and the 2nd flat plate part 67 are not connected, but are connected by folding (it includes the case where a micro clearance gap is vacant). The same applies to the second magnetic member 7C.

  The second flat plate portions 67 and 77 are connected to each of the first side plate portions 61B and 71B and each of the second side plate portions 62B and 72B, and cover the lower side of the corresponding magnetic field detection unit 5 in the axis AX direction. It extends vertically.

  Note that the shapes and the like of the magnetic members 6C and 7C described above are merely examples, and shapes other than those described above may be used. Further, the molding method of the first magnetic member 6C is not limited to the above. For example, even if the first magnetic member 6C is formed by connecting the first side plate portion 61B, the second side plate portion 62B, the first flat plate portion 65, and the second flat plate portion 67 made of different plate materials by welding or the like. Good. Further, for example, the first magnetic member 6C may be integrally formed by casting. The same applies to the second magnetic member 7C.

(1-4-3-2. Magnetic field induction function of magnetic member and operation of magnetic field detector)
Next, an example of the magnetic field induction function of the magnetic members 6C and 7C and the operation of the magnetic field detection unit 5 will be described with reference to FIGS. 9A and 9B.

  As shown in FIGS. 9A and 9B, when the magnet 4a faces the first magnetic member 6Ca and the magnet 4d faces the second magnetic member 7Ca, the first side plate portion 61B of the first magnetic member 6Ca, the second See FIG. 7A and FIG. 7B for the magnetic field induction functions of the side plate portion 62B, the first flat plate portion 65, and the first side plate portion 71B, the second side plate portion 72B, and the first flat plate portion 75 of the second magnetic member 7Ca. However, it is almost the same as described above. Therefore, here, an example of the magnetic field induction function of the second side plate portion 67 of the first magnetic member 6Ca and the second side plate portion 77 of the second magnetic member 7Ca will be mainly described.

  That is, part of the magnetic flux that has entered the first magnetic member 6Ca from the magnet 4a also enters the second flat plate portion 67 that is connected to the first side plate portion 61B. Most of the magnetic flux travels in the second flat plate portion 67 toward the second magnetic member 7Ca. At this time, since the magnetic members 6Ca and 7Ca are separated via a gap, the magnetic flux that has traveled toward the second magnetic member 7Ca in the second flat plate portion 67 is below the magnetic field detecting portion 5a. Then, the magnetic field detection unit 5a enters a portion slightly on the one side of the central portion in the length direction. This magnetic flux travels in the magnetic field detector 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches a portion on the other side slightly from the central portion. This magnetic flux leaves the magnetic field detection unit 5a and enters the second magnetic member 7Ca below the magnetic field detection unit 5a. This magnetic flux travels toward the magnet 4d in the second flat plate portion 77 of the second magnetic member 7Ca, and eventually reaches the magnet 4d via the first side plate portion 71B.

  Further, part of the magnetic flux that has entered the second flat plate portion 67 of the first magnetic member 6Ca travels in the second flat plate portion 67 toward the side opposite to the second magnetic member 7Ca side. This magnetic flux enters a portion on one end side in the length direction of the magnetic field detection unit 5a below the magnetic field detection unit 5a. The magnetic flux travels in the magnetic field detection unit 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches a portion on the other side in the length direction. This magnetic flux leaves the magnetic field detector 5a and enters the second magnetic member 7Ca. This magnetic flux travels toward the magnet 4d in the second flat plate portion 77 of the second magnetic member 7Ca, and eventually reaches the magnet 4d via the first side plate portion 71B.

  As described above, when the magnet 4a faces the first magnetic member 6Ca and the magnet 4d faces the second magnetic member 7Ca, most of the magnetic flux from the magnet 4a toward the magnet 4d is caused by the magnetic members 6Ca and 7Ca. Be guided. Thereby, for example, a relatively strong magnetic path (magnetic field) passing through the vicinity of the central portion in the length direction of the magnetic field detector 5a as shown by the thick solid line arrow in FIGS. 9A and 9B is formed. Further, for example, a relatively weak magnetic field from the one end side in the length direction of the magnetic field detection unit 5a to the other end side as shown by a thick broken line arrow in FIGS. 9A and 9B is also formed.

  By applying the magnetic field as described above to the magnetic field detection unit 5a, the outer peripheral portion of the magnetic element 51 of the magnetic field detection unit 5a is magnetized in the direction indicated by the block arrows in FIGS. 9A and 9B. Therefore, when the previous magnetization direction of the magnetic element 51 is opposite to the block arrow, the magnetization direction of the magnetic element 51 is reversed, and a pulse signal in the positive direction is output from the coil 52 of the magnetic field detector 5a. Is done.

  Note that the magnetic field induction function of the magnetic members 6C and 7C and the operation of the magnetic field detection unit 5 described above are merely examples, and modes other than the above may be used.

(1-4-3-3. Examples of effects of this modification)
Also in this modified example described above, the same effect as the modified example (1-4-2) can be obtained. Furthermore, in this modification, the magnetic members 6C and 7C have both the first flat plate portions 65 and 75 and the second flat plate portions 67 and 77, so that the magnetic members 6C and 7C are applied to the magnetic field detection unit 5 as compared with the case where either one is provided. The magnetic field to be applied can be further increased, and the magnetic stability and efficiency can be further improved. Moreover, the influence of the dimensional tolerance and the position tolerance in the axis AX direction of the magnetic field detector 5 can be reduced. Furthermore, the influence of the disturbance magnetic field from both the upper part and the lower part can be reduced.

(1-4-4. Another example of configuration of magnetic member [part 4])
In this modification, the first magnetic member and the second magnetic member have a first flat plate portion covering the upper side of the magnetic field detection unit 5 in addition to the first side plate portion and the second side plate portion, and the radial direction of the magnetic field detection unit 5. It is an example in the case of providing the 4th side board part which covers an outside.

(1-4-4-1. Configuration of Rotation Detection Device)
Hereinafter, an example of the configuration of the rotation detection device 1D according to this modification will be described with reference to FIGS. 10A, 10B, and 10C. In FIG. 10A, for convenience of description of the structure of the rotation detection device 1, the illustration of a pair of first magnetic member and second magnetic member corresponding to the magnetic field detection unit 5 a is omitted. 10A to 10C, the housing 2 and the substrate 8 are not shown.

  As shown in FIGS. 10A to 10C, in the rotation detection device 1D, the configurations different from the rotation detection device 1 according to the embodiment are the first magnetic member, the second magnetic member, and the like, and the shaft 3 and the magnets 4a to 4d. The magnetic field detectors 5a to 5c are the same as those in the above embodiment.

  The first magnetic members 6Da, 6Db, and 6Dc (hereinafter collectively referred to as “first magnetic member 6D” as appropriate) according to the present modification are magnets 4a to 4d on one side in the length direction of each of the magnetic field detectors 5a to 5c. It is being fixed to the housing 2 so that the part etc. which oppose may be covered. Further, the second magnetic members 7Da, 7Db, and 7Dc (hereinafter collectively referred to as “second magnetic member 7D” as appropriate) are opposed to the magnets 4a to 4d on the other side in the length direction of the magnetic field detectors 5a to 5c. It is being fixed to the housing 2 so that a part etc. may be covered. The magnetic members 6Da and 7Da, the magnetic members 6Db and 7Db, and the magnetic members 6Dc and 7Dc are arranged with a gap at the central portion in the length direction of the corresponding magnetic field detector 5, and the axis AX and the corresponding magnetic field The plane is symmetrical with a plane composed of a line passing through a central portion in the length direction of the detection unit 5 and a point having the shortest distance on the axis AX as a plane of symmetry.

  In the present modification, the first magnetic members 6Da to 6Dc include the first side plate portion 61B, the second side plate portion 62B, the first flat plate portion 65, and the fourth side plate portion 64D, which are the same as those of the rotation detection device 1B. . Moreover, 2nd magnetic member 7Da-7Dc has the 1st side board part 71B similar to the said rotation detection apparatus 1B, the 2nd side board part 72B, the 1st flat plate part 75, and 4th side board part 74D. The first magnetic member 6D is formed, for example, by forming a single flat plate into a desired shape by punching or the like, and bending it by pressing or the like, so that the first side plate portion 61B, the second side plate portion 62B, the first flat plate portion 65, And the 4th side board part 64D is formed. For this reason, for example, the first side plate portion 61B is connected to each of the second side plate portion 62B and the first flat plate portion 65, and the first flat plate portion 65 is connected to the fourth side plate portion 64D. The part 62B and the first flat plate part 65 are not connected but are connected by folding (including a case where a minute gap is open). The same applies to the second magnetic member 7D.

  The fourth side plate portions 64D and 74D are basically the same as the above-described fourth side plate portions 64 and 74, are connected to the first flat plate portions 65 and 75, and the magnetic field on the outer side in the radial direction of the corresponding magnetic field detection unit 5. It extends along the length direction of the detector 5.

  Note that the shapes and the like of the magnetic members 6D and 7D described above are merely examples, and shapes other than those described above may be used. Further, the molding method of the first magnetic member 6D is not limited to the above. For example, even if the first magnetic member 6D is formed by connecting the first side plate portion 61B, the second side plate portion 62B, the first flat plate portion 65, and the fourth side plate portion 64D made of different plate materials by welding or the like. Good. Further, for example, the first magnetic member 6D may be integrally formed by casting. The same applies to the second magnetic member 7D.

(1-4-4-2. Magnetic member magnetic field induction function and operation of magnetic field detector)
Next, an example of the magnetic field induction function of the magnetic members 6D and 7D and the operation of the magnetic field detection unit 5 will be described with reference to FIGS. 11A and 11B.

  As shown in FIGS. 11A and 11B, when the magnet 4a faces the first magnetic member 6Da and the magnet 4d faces the second magnetic member 7Da, the first side plate portion 61B of the first magnetic member 6Da, the second See FIG. 7A and FIG. 7B for the magnetic field induction functions of the side plate portion 62B, the first flat plate portion 65, and the first side plate portion 71B, the second side plate portion 72B, and the first flat plate portion 75 of the second magnetic member 7Da. However, it is almost the same as described above. Therefore, here, an example of the magnetic field induction function of the fourth side plate portion 64D of the first magnetic member 6Da and the fourth side plate portion 74D of the second magnetic member 7Da will be mainly described.

  That is, part of the magnetic flux that has traveled from the magnet 4a through the first side plate portion 61B and the first flat plate portion 65 of the first magnetic member 6Da enters the fourth side plate portion 64D that is connected to the first flat plate portion 65, and It advances toward the second magnetic member 7Da side in the fourth side plate portion 64D. At this time, since the magnetic members 6Da and 7Da are separated by a gap, most of the magnetic flux that has traveled toward the second magnetic member 7Da in the fourth side plate portion 64D is generated by the magnetic field detector 5a. On the outer side in the radial direction, the magnetic field detector 5a enters a portion slightly on the one side with respect to the central portion in the length direction. This magnetic flux travels in the magnetic field detector 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches a portion on the other side slightly from the central portion. This magnetic flux leaves the magnetic field detection unit 5a and enters the second magnetic member 7Da outside the magnetic field detection unit 5a in the radial direction. This magnetic flux travels through the fourth side plate portion 74D of the second magnetic member 7Da, and eventually reaches the magnet 4d via the first flat plate portion 75 and the first side plate portion 71B.

  Further, a part of the magnetic flux that has entered the fourth side plate portion 64D of the first magnetic member 6Da enters a portion on one end side in the length direction of the magnetic field detection unit 5a on the outer side in the radial direction of the magnetic field detection unit 5a. The magnetic flux travels in the magnetic field detection unit 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches a portion on the other side in the length direction. This magnetic flux leaves the magnetic field detector 5a and enters the second magnetic member 7Da. This magnetic flux travels through the fourth side plate portion 74D of the second magnetic member 7Da, and eventually reaches the magnet 4d via the first flat plate portion 75 and the first side plate portion 71B.

  As described above, when the magnet 4a faces the first magnetic member 6Da and the magnet 4d faces the second magnetic member 7Da, most of the magnetic flux from the magnet 4a toward the magnet 4d is caused by the magnetic members 6Da and 7Da. Be guided. Thereby, for example, a relatively strong magnetic path (magnetic field) passing through the vicinity of the central portion in the length direction of the magnetic field detection unit 5a as shown by the thick solid arrow in FIGS. 11A and 11B is formed. Further, for example, a relatively weak magnetic field from the one end side in the length direction of the magnetic field detection unit 5a to the other end side as shown by a thick broken line arrow in FIGS. 11A and 11B is also formed.

  By applying the magnetic field as described above to the magnetic field detection unit 5a, the outer peripheral portion of the magnetic element 51 of the magnetic field detection unit 5a is magnetized in the direction indicated by the block arrows in FIGS. 11A and 11B. Therefore, when the previous magnetization direction of the magnetic element 51 is opposite to the block arrow, the magnetization direction of the magnetic element 51 is reversed, and a pulse signal in the positive direction is output from the coil 52 of the magnetic field detector 5a. Is done.

  The magnetic field induction function of the magnetic members 6D and 7D and the operation of the magnetic field detection unit 5 described above are merely examples, and other aspects may be used.

(1-4-4-3. Examples of effects of this modification)
Also in this modified example described above, the same effect as in the above embodiment can be obtained. Furthermore, in this modified example, the magnetic members 6D and 7D have the fourth side plate portions 64D and 74D, so that the magnetic field applied to the magnetic field detection unit 5 can be made stronger, and the magnetic stability and efficiency are improved. it can. Further, the influence of the dimensional tolerance and the position tolerance in the radial direction of the magnetic field detector 5 can be reduced, and the influence of the disturbance magnetic field from the outside in the radial direction can be reduced.

  Moreover, in this modification, the magnetic members 6D and 7D have the first flat plate portions 65 and 75, so that the magnetic field applied to the magnetic field detection unit 5 can be made stronger, and the magnetic stability and efficiency are improved. it can. Furthermore, the influence of the disturbance magnetic field from the upper part can be reduced.

(1-4-5. When magnets are arranged on the outer peripheral side of the magnetic field detector and magnetic member)
In the said embodiment, the magnet 4 was arrange | positioned in order of the magnet 4, the 1st and 2nd magnetic members 6 and 7, and the magnetic field detection part 5 from the inner peripheral side, ie, radial inner side toward the outer side. However, the positional relationship among the magnet, the first and second magnetic members, and the magnetic field detection unit is not limited to the above. For example, the magnet 4 may be arranged in the order of the magnetic field detector 5, the first and second magnetic members 6 and 7, and the magnet 4 from the outer peripheral side, that is, from the inner side to the outer side in the radial direction.

(1-4-5-1. Configuration of rotation detection device)
Hereinafter, an example of the configuration of the rotation detection device 1E according to the present modification will be described with reference to FIGS. 12A and 12B. 12A and 12B, the housing 2, the shaft 3, and the substrate 8 are not shown.

  As illustrated in FIGS. 12A and 12B, the rotation detection device 1 </ b> E includes a cylindrical member 30. The cylindrical member 30 is supported by the housing 2 so as to be rotatable about the axis AX as a rotation axis. Specifically, the cylindrical member 30 is connected to the shaft 3 and rotates around the axis AX in conjunction with the rotation of the shaft 3. The aforementioned magnets 4a to 4d are fixed to the inner periphery of the cylindrical member 30 in the circumferential direction by, for example, adhesion. That is, in this modification, the cylindrical member 30 corresponds to an example of a magnet support, and the axial center AX direction corresponds to an example of a rotation axis direction.

  Accordingly, the magnets 4 a to 4 d rotate around the axis AX in conjunction with the rotation of the cylindrical member 30. At this time, the magnets 4a to 4d are arranged so that the centers of the respective rotation locus circles R1 to R4 are on the axis AX, and the radii (circumferences) of the respective rotation locus circles R1 to R4 are equal to each other. Rotate around AX. The magnets 4a to 4d are magnetized in the radial direction, and are arranged so that the radially inner magnetic poles alternate in the circumferential direction. For example, the magnets 4a to 4d are arranged such that the radially inner magnetic poles are N poles, S poles, N poles, and S poles. The magnets 4a to 4d are arranged, for example, at regular intervals (90 ° intervals) in the circumferential direction. In FIG. 12A, only the magnetic poles on the inner side in the radial direction of the magnet 4c are shown, and the magnetic poles of the magnets 4b and 4d are not shown. Moreover, in FIG. 12B, illustration of the magnetic poles of the magnets 4a to 4d is omitted.

  The cylindrical member 30 may be directly connected to the detection target without being connected to the shaft 3. In the example shown in FIG. 12, the magnet fixing portion of the cylindrical member 30 is a flat plate shape, but the entire cylindrical member 30 may be a cylindrical shape and the arc-shaped magnet 4 may be fixed.

  The first magnetic members 6Ea, 6Eb, 6Ec according to the present modification (hereinafter collectively referred to as “first magnetic member 6E” where appropriate) are arranged on one side in the length direction on the outer side in the radial direction of the magnetic field detectors 5a-5c. It is being fixed to the housing 2 via the above-mentioned board | substrate 8 so that the part etc. which oppose the magnets 4a-4d may be covered. The second magnetic members 7Ea, 7Eb, 7Ec (hereinafter collectively referred to as “second magnetic member 7E” where appropriate) are arranged on the other side in the radial direction of the magnetic field detectors 5a-5c. It is fixed to the housing 2 via the above-described substrate 8 so as to cover a portion facing 4d and the like.

  The magnetic members 6Ea and 7Ea, the magnetic members 6Eb and 7Eb, and the magnetic members 6Ec and 7Ec are arranged with a gap at the central portion in the length direction of the corresponding magnetic field detector 5, and the axis AX and the corresponding magnetic field The plane is symmetrical with a plane composed of a line passing through a central portion in the length direction of the detection unit 5 and a point having the shortest distance on the axis AX as a plane of symmetry.

  As described above, in this modification, the magnets 4 a to 4 d are fixed to the inner periphery of the cylindrical member 30. And the magnetic field detection parts 5a-5c are arrange | positioned at the inner peripheral side of the cylindrical member 30. FIG. In addition, magnetic members 6Ea to 6Ec and 7Ea to 7Ec are arranged between the magnets 4a to 4d and the magnetic field detectors 5a to 5c in the radial direction. That is, the magnetic field detectors 5a to 5c, the magnetic members 6Ea to 6Ec, 7Ea to 7Ec, and the magnets 4a to 4d are arranged in this order from the inner side to the outer side in the radial direction.

  In addition, the structure of the rotation detection apparatus 1E demonstrated above is an example to the last, and structures other than the above may be sufficient.

(1-4-5-2. Magnetic member magnetic field induction function and operation of magnetic field detector)
Next, an example of the magnetic field induction function of the magnetic members 6E and 7E and the operation of the magnetic field detector 5 will be described with reference to FIG.

  As shown in FIG. 13, when the magnet 4a faces the first magnetic member 6Ea and the magnet 4d faces the second magnetic member 7Ea, most of the magnetic flux from the magnet 4a to the magnet 4d is from the magnet 4a. It enters the first magnetic member 6Ea.

  Most of the magnetic flux that has entered the first magnetic member 6Ea from the magnet 4a travels in the first magnetic member 6Ea toward the second magnetic member 7Ea. At this time, since the magnetic members 6Ea and 7Ea are separated by a gap, the magnetic flux that has traveled in the first magnetic member 6Ea toward the second magnetic member 7Ea is on the outer side in the radial direction of the magnetic field detector 5a. Then, the magnetic field detection unit 5a enters a portion slightly on the one side of the central portion in the length direction. This magnetic flux travels in the magnetic field detector 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches a portion on the other side slightly from the central portion. This magnetic flux leaves the magnetic field detection unit 5a and enters the second magnetic member 7Ea outside the magnetic field detection unit 5a in the radial direction. This magnetic flux travels in the second magnetic member 7Ea toward the magnet 4d, and eventually reaches the magnet 4d.

  Further, part of the magnetic flux that has entered the first magnetic member 6Ea from the magnet 4a travels in the first magnetic member 6Ea toward the side opposite to the second magnetic member 7Ea. A part of the magnetic flux enters a portion on one end side in the length direction of the magnetic field detector 5a. This magnetic flux travels in the magnetic field detector 5a toward the other side in the length direction, passes through the central portion in the length direction, and reaches the portion on the other side in the length direction. This magnetic flux leaves the magnetic field detector 5a and enters the second magnetic member 7Ea. This magnetic flux travels in the second magnetic member 7Ea toward the magnet 4d, and eventually reaches the magnet 4d.

  As described above, when the magnet 4a faces the first magnetic member 6Ea and the magnet 4d faces the second magnetic member 7Ea, most of the magnetic flux from the magnet 4a toward the magnet 4d is caused by the magnetic members 6Ea and 7Ea. Be guided. Thereby, for example, a relatively strong magnetic path (magnetic field) passing through the vicinity of the central portion in the length direction of the magnetic field detector 5a as shown by the thick solid arrow in FIG. 13 is formed. Further, for example, a relatively weak magnetic field from the one end side in the length direction of the magnetic field detector 5a to the other end side as shown by the thick broken line arrow in FIG. 13 is also formed.

  By applying the magnetic field as described above to the magnetic field detector 5a, the outer peripheral portion of the magnetic element 51 of the magnetic field detector 5a is magnetized in the direction indicated by the block arrow in FIG. Therefore, when the previous magnetization direction of the magnetic element 51 is opposite to the block arrow, the magnetization direction of the magnetic element 51 is reversed, and a pulse signal in the positive direction is output from the coil 52 of the magnetic field detector 5a. Is done.

  Note that the magnetic field induction function of the magnetic members 6E and 7E and the operation of the magnetic field detection unit 5 described above are merely examples, and modes other than the above may be used.

(1-4-5-3. Examples of effects of this modification)
Also in this modified example described above, the axial dimension of the rotation detection device 1E can be reduced as in the above embodiment. Further, the magnetic field induction function of the magnetic members 6E and 7E can prevent a change in the magnetization direction of the magnetic element 51 from being difficult to predict, and can increase the detection accuracy of the detection target.

(1-4-6. When fixing a ring magnet)
In the said embodiment and each modification, although the magnets 4a-4b which are flat magnets were used as a magnet, you may use a ring magnet. Here, the case where the magnets 4a to 4e of the rotation detection device 1B are changed to ring magnets among the rotation detection devices 1 and 1A to 1E will be described as a representative, but the other rotation detection devices 1, 1A and 1C to 1E are described. It is also possible to change the 1E magnets 4a to 4e to ring magnets.

  Hereinafter, an example of the configuration of the rotation detection device 1F according to the present modification will be described with reference to FIGS. 14A and 14B. 14A is a view corresponding to FIG. 6B described above, and FIG. 14B is a perspective view showing an example of a shaft having a ring magnet fixed to the outer periphery.

  As shown in FIGS. 14A and 14B, in the rotation detection device 1F, the configurations different from the rotation detection device 1B described above are a shaft and a magnet, and magnetic field detection units 5a to 5c, magnetic members 6Ba to 6Bc, 7Ba to 7Bc, and the like. Is the same as the rotation detection device 1B described above.

  That is, the rotation detection device 1F includes a shaft 3F instead of the above-described shaft 3, and includes a ring magnet 4F instead of the above-described magnets 4a to 4d.

  The shaft 3F is rotatably supported by the housing 2 with the axis AX as a rotation axis, and is formed in a cylindrical shape over the entire region of the axis AX. On the outer periphery of the shaft 3F, a ring magnet 4F (corresponding to an example of a magnet) is fixed by, for example, a holder. That is, in this modification, the shaft 3F corresponds to an example of a magnet support, and the axial center AX direction corresponds to an example of a rotation axis direction.

  The ring magnet 4F is magnetized in the radial direction, and includes four magnetic pole portions 4Fa, 4Fb, 4Fc, and 4Fd provided such that the magnetic poles on the outer side in the radial direction are alternately arranged in the circumferential direction. For example, the magnetic pole portions 4Fa, 4Fb, 4Fc, and 4Fd are arranged such that the magnetic poles on the outer side in the radial direction are N poles, S poles, N poles, and S poles. That is, the descriptions “N” and “S” shown in FIG. 14B correspond to the magnetic poles on the radially outer side of the magnetic pole portions. In FIG. 14A, the magnetic poles of the magnetic pole portions 4Fa to 4Fd are not shown.

  The ring magnet 4F may be fixed to the outer periphery of the shaft 3F as a plurality of arc-shaped magnets.

  In this modification, by using the ring magnet 4F, the magnetic field can be made stronger and the magnetic stability and efficiency can be improved as compared with the case of using a flat magnet. Further, the strength against the centrifugal force is increased, and the holding structure to the shaft 3F can be simplified.

(1-4-7. When covering the periphery with a shield member)
Of the above-described embodiments and modifications, examples in which the outer sides in the radial direction of the magnetic field detectors 5a to 5c are not covered with the first and second magnetic members (for example, rotation detection devices 1, 1B, 1C, 1F, etc.) The magnetic field detectors 5a to 5b may be surrounded by a shield member made of a magnetic material. Here, the case where the periphery of the magnetic field detectors 5a to 5c of the rotation detection device 1F is covered by a shield member among the rotation detection devices 1 and 1A to 1F described above will be described as a representative. Can be covered with a shield member.

  Hereinafter, an example of the configuration of the rotation detection device 1G according to this modification will be described with reference to FIG.

  As shown in FIG. 15, the rotation detection device 1G is different from the rotation detection device 1F described above in that a shield member is disposed, and the other points are the same as those of the rotation detection device 1F described above.

  That is, for example, a cylindrical shield member 10 is disposed in the rotation detection device 1G. The shield member 10 is made of a magnetic material, and is fixed to the housing 2 so as to cover the periphery of the magnetic field detectors 5a to 5c and the like.

  Thus, by arranging the shield member 10 around the magnetic field detectors 5a to 5c, the influence of the disturbance magnetic field from the outside in the radial direction can be reduced.

  The first embodiment and the modifications thereof have been described above. The rotation detection devices 1 and 1A to 1G according to the first embodiment and the modifications thereof can be used in various modes, and usage modes including a detection target are not particularly limited. For example, the object to be detected can be a motor, and the rotation detection devices 1 and 1A to 1G can be assembled to the motor. However, in the rotation detection devices 1 and 1A to 1G, the detection target may be a rotation device other than the motor, or may not be assembled to the detection target.

  Hereinafter, as an example of a usage mode of the rotation detection devices 1 and 1A to 1G, an embodiment in which the detection target is a motor and the rotation detection devices 1 and 1A to 1G are assembled to the motor will be described.

<2. Second Embodiment>
Hereinafter, a second embodiment which is an example of a usage mode of the rotation detection devices 1 and 1A to 1G will be described. Here, of the rotation detection devices 1 and 1A to 1G, the case where the rotation detection device 1 is assembled to a motor will be described as a representative, but other rotation detection devices 1A to 1G may be assembled to a motor and used. Is possible.

(2-1. Motor configuration)
Hereinafter, an example of the configuration of the motor according to the present embodiment will be described with reference to FIG. In FIG. 16, for convenience of explanation of the structure of the motor, the configuration of the rotation detection device 1 is shown in a state viewed from the side, and the other configuration is shown in a sectional view and seen through the housing. .

  As illustrated in FIG. 16, the motor M1 includes a motor shaft SH, a motor electromagnetic unit 200, and an encoder 100 including the rotation detection device 1 described above.

  The shaft 3 of the rotation detection device 1 is connected to the end of the motor shaft SH so as to have the same axis.

  The motor electromagnetic unit 200 outputs a rotational force by rotating the motor shaft SH around its axis AX. In the present specification, the rotational force output side of the motor electromagnetic unit 200 is referred to as “load side” and the opposite side is referred to as “anti-load side”.

  Here, for convenience of the description of the structure of the motor M1, in the following, directions such as up and down are determined as follows and used appropriately. That is, in FIG. 16, the anti-load side direction, that is, the Z-axis positive direction is defined as “up”, and the reverse load side direction, that is, the Z-axis negative direction is defined as “down”. However, directions such as up and down vary depending on the installation mode of the motor M1, and do not limit the positional relationship of each component of the motor M1.

  The configuration of the motor electromagnetic unit 200 is not particularly limited as long as the motor shaft SH can be rotated. For example, the configuration is as follows.

  That is, the motor electromagnetic unit 200 includes a stator 201 and a rotor 202 arranged on the inner peripheral side of the stator 201. That is, the motor electromagnetic unit 200 is configured as a so-called “inner rotor type” in which the rotor 202 is disposed on the inner peripheral side of the stator 201.

  The rotor 202 is fixed to the outer periphery of the motor shaft SH so as to be coaxial with the motor shaft SH that is rotatably supported by the bearings 206 and 207.

  The stator 201 is fixed to the inner periphery of the frame 203 and is supported by brackets 204 and 205 to which outer rings of bearings 206 and 207 are fitted so as to face the outer periphery of the rotor 202 via a magnetic gap in the radial direction. It is supported.

  The motor electromagnetic unit 200 configured as described above can rotate the motor shaft SH around the axis AX by rotating the rotor 202 around the axis AX with respect to the stator 201.

  The configuration of the motor electromagnetic unit 200 described above is merely an example, and a configuration other than the above may be used. For example, the motor electromagnetic unit 200 is not limited to being configured as an inner rotor type, and may be configured as a so-called “outer rotor type” in which a rotor is disposed on the outer peripheral side of the stator.

  The encoder 100 is disposed adjacent to, for example, the upper side of the motor electromagnetic unit 200. The configuration of the encoder 100 is not particularly limited as long as it can detect at least the rotation state (for example, the rotation direction and the number of rotations) of the motor electromagnetic unit 200 by the rotation detection device 1. Configured.

  That is, the encoder 100 includes the rotation detection device 1, the disk 101, the encoder board 103, the optical module 104, and a control unit (not shown). The encoder 100 is covered with the housing 2 described above, and the shaft 3 is connected to the upper end of the motor shaft SH so as to be rotatable around the axis AX with respect to the housing 2. For example, it is fixed to the upper surface of the bracket 204 with a bolt or the like.

  In the rotation detection device 1 (refer to the above-described FIG. 1, FIG. 2A, and FIG. 2B for the detailed structure), the substrate 8 is fixed to the housing 2 in a state where the substrate 8 is disposed on the lower side.

  The disk 101 is connected to the upper end portion of the shaft 3 via the hub 102 so that the center of rotation coincides with the axis AX. That is, the disk 101 rotates around the axis AX in conjunction with the rotation of the shaft 3. One or more tracks (not shown) in which a plurality of reflective slits (not shown) are arranged along the circumferential direction are formed on the upper surface of the disk 101. The reflection slit reflects light emitted from the light source 105 described later. As an arrangement pattern of the reflection slits in the track, for example, an “incremental pattern” in which the reflection slits are regularly repeated at a predetermined pitch, or the position and ratio of the reflection slits are uniquely determined within one rotation of the disk 101. Absolute pattern "etc. are mentioned, It does not specifically limit.

  The encoder board 103 is disposed on the upper side of the disk 101 while being separated from the disk 101, and is fixed to the housing 2 via a support member (not shown). Some electronic devices on the encoder substrate 103 are connected to some electronic devices on the substrate 8 by, for example, cables.

  The optical module 104 is attached to the lower surface of the encoder substrate 103 so as to be parallel to the disk 101 and to face a part of the track. A light source 105 is provided on the lower surface of the optical module 104, and one or more light receiving arrays (not shown) in which a plurality of light receiving elements are arranged along the circumferential direction of the disk 101 are provided. The light source 105 is composed of, for example, an LED or the like, and emits light to a part of the track passing through the facing position. The light receiving element is composed of, for example, a photodiode, receives light reflected by the reflection slit of the track passing through a position opposed to the light source 105, and outputs a light reception signal.

  The control unit can detect the rotation state (for example, the rotation direction and the number of rotations) of the motor electromagnetic unit 200 based on the light reception signal output from each light receiving element.

  The configuration of the motor M1 described above is merely an example, and a configuration other than the above may be used. For example, the disc 101 is connected to the shaft 3 via the hub 102, but may be directly connected to the shaft 3 without the hub 102. The encoder 100 includes a so-called “reflective” optical detection mechanism, but may instead include a so-called “transmissive” optical detection mechanism. Further, the encoder 100 is disposed adjacent to the upper side of the motor electromagnetic unit 200, but another configuration such as an electromagnetic brake is disposed on the upper side of the motor electromagnetic unit 200, and the other is disposed on the upper side of the motor electromagnetic unit 200. You may arrange | position through this structure.

(2-2. Examples of effects according to this embodiment)
Since the motor M1 of the present embodiment described above includes the rotation detection device 1 according to the first embodiment, the same effect as that of the first embodiment can be obtained. Therefore, the axial dimension of the motor M1 provided with the rotation detection device 1 can be reduced. Further, as described above, the magnetic field induction function of the magnetic members 6a to 6c and 7a to 7c of the rotation detection device 1 prevents an unpredictable change in the magnetization direction of the magnetic element 51, thereby detecting the rotation accuracy of the motor electromagnetic unit 200. Can be increased.

  In the above description, the motor M1 including the rotation detection device 1 according to the first embodiment has been described as an example, and thus the motor M1 can obtain the same effects as those of the first embodiment. However, when the motor M1 includes the other rotation detection devices 1A to 1G, it is possible to obtain the same effect as the modification of the first embodiment related to the other rotation detection devices 1A to 1G.

<3. Third Embodiment>
Next, 3rd Embodiment which is another example of the usage condition of rotation detection apparatus 1,1A-1G is described. Here, of the rotation detection devices 1 and 1A to 1G, a case where the rotation detection device 1B is assembled to a motor will be described as a representative, but other rotation detection devices 1, 1A and 1C to 1G are assembled to a motor. It is also possible to use it.

(3-1. Motor configuration)
Hereinafter, an example of the configuration of the motor according to the present embodiment will be described with reference to FIG.

  As shown in FIG. 17, the motor M2 is different from the motor M1 according to the second embodiment in the configuration of the encoder, and the other points are the same as those of the motor M1 according to the second embodiment.

  Here, for convenience of the description of the structure of the motor M2, hereinafter, directions such as up and down are determined as follows and used appropriately. That is, in FIG. 17, the anti-load side direction, that is, the Z-axis positive direction is defined as “up”, and the reverse load side direction, that is, the Z-axis negative direction is defined as “down”. However, the direction such as up and down varies depending on the installation mode of the motor M2, and does not limit the positional relationship of each component of the motor M2. The direction such as up and down defined here is opposite to the direction such as up and down defined in the modification of the first embodiment relating to the rotation detection device 1B (see FIGS. 6A to 6C described above).

  The encoder 100 </ b> A of the motor M <b> 2 is disposed adjacent to, for example, the upper side of the motor electromagnetic unit 200. The configuration of the encoder 100A is not particularly limited as long as it can detect at least the rotation state (for example, the rotation direction and the number of rotations) of the motor electromagnetic unit 200 by the rotation detection device 1B. Configured.

  That is, the encoder 100A includes the rotation detection device 1B, the disk 101, the encoder board 103A, the optical module 104, and the control unit. Similarly to the encoder 100 described above, the encoder 100 </ b> A is covered by the housing 2, the shaft 3 is connected to the upper end of the motor shaft SH so as to be rotatable with respect to the housing 2, and the housing 2 is the upper surface of the bracket 204. It is fixed to.

  In the rotation detection device 1B (refer to the above-described FIGS. 6A to 6C for the detailed structure), the substrate 8 is disposed on the upper side, and the first flat plate portions 65 and 75 of the magnetic members 6Ba to 6Bc and 7Ba to 7Bc are provided. In a state of being disposed on the lower side, the substrate 8 is fixed to the housing 2 via a support member (not shown), and the first flat plate portions 65 and 75 are fixed to the housing 2.

  In this embodiment, the disk 101 is connected to the upper end portion of the shaft 3 via a hub 102A so that the surface on which the above-described track is formed becomes the lower surface.

  The encoder substrate 103A has a through hole 1031. The encoder board 103A is fixed to the housing 2 via a support member (not shown) through the shaft 3 through the through hole 1031 so that the encoder board 103A is disposed below the disk 101 while being separated from the disk 101. . That is, the encoder substrate 103A is disposed immediately above the substrate 8 of the rotation detection device 1B. Some electronic devices on the encoder substrate 103A are connected to some electronic devices on the substrate 8 by, for example, cables or connectors.

  In this embodiment, the optical module 104 is attached to the upper surface of the encoder substrate 103A so as to be able to face a part of the track. That is, in the present embodiment, the light source 105 and the light receiving array described above are provided on the upper surface of the optical module 104.

  The configuration of the motor M2 described above is merely an example, and a configuration other than the above may be used. For example, although the disc 101 is connected to the shaft 3 via the hub 102A, it may be directly connected to the shaft 3 without going through the hub 102A. In addition, the encoder 100A includes a so-called “reflection type” optical detection mechanism, but may instead include a so-called “transmission type” optical detection mechanism. The encoder 100A is disposed adjacent to the upper side of the motor electromagnetic unit 200. However, another configuration such as an electromagnetic brake is disposed on the upper side of the motor electromagnetic unit 200, and the other is disposed on the upper side of the motor electromagnetic unit 200. You may arrange | position through this structure.

(3-2. Examples of effects according to this embodiment)
Since the motor M2 of the present embodiment described above includes the rotation detection device 1B according to the second modification of the first embodiment, the same effect as that of the second modification can be obtained. Therefore, the axial dimension of the motor M2 provided with the rotation detection device 1B can be reduced. Further, as described above, the magnetic field induction function of the magnetic members 6Ba to 6Bc and 7Ba to 7Bc of the rotation detection device 1B prevents an unpredictable change in the magnetization direction of the magnetic element 51, thereby detecting the rotation detection accuracy of the motor electromagnetic unit 200. Can be increased.

  Further, in the present embodiment, the rotation detection device 1B is installed so that the first flat plate portions 65 and 75 of the magnetic members 6Ba to 6Bc and 7Ba to 7Bc are arranged on the lower side (motor electromagnetic unit 200 side). Thereby, the influence of the magnetic field from the motor electromagnetic unit 200 can be reduced, and the detection accuracy of the rotation of the motor electromagnetic unit 200 can be increased. And when the electromagnetic brake is arrange | positioned between the rotation detection apparatus 1B and the motor electromagnetic part 200, since the said structure can also reduce the influence of the magnetic field from the said electromagnetic brake, it is especially effective. It is.

  In the present embodiment, the encoder substrate 103A and the substrate 8 of the rotation detection device 1B can be disposed close to each other. As a result, the connection configuration (cable, connector, etc.) between the boards can be simplified, and the noise on the signals transmitted and received between the boards can be reduced by shortening the connection distance, thereby improving the reliability of the encoder 100A.

  In the above description, the motor M2 including the rotation detection device 1B according to the second modification of the first embodiment has been described as an example, and therefore the motor M2 is the second modification of the first embodiment. The same effect was obtained. However, when the motor M2 includes the other rotation detection devices 1, 1A, 1C to 1G, the same as the first embodiment and the modifications thereof related to the other rotation detection devices 1, 1A, 1C to 1G. An effect can be obtained.

  In the above description, when there are descriptions such as “vertical”, “parallel”, and “center”, the descriptions are not strict. That is, the terms “vertical”, “parallel”, and “center” allow tolerances and errors in design and mean “substantially vertical”, “substantially parallel”, and “substantially center”. .

  In addition, in the above description, when there are descriptions such as “same”, “equal”, “different”, etc., in terms of external dimensions and sizes, the descriptions are not strict. That is, the terms “identical”, “equal”, and “different” mean that “tolerance and error in manufacturing are allowed in design and that they are“ substantially identical ”,“ substantially equal ”, and“ substantially different ”. .

DESCRIPTION OF SYMBOLS 1 Rotation detection apparatus 1A-1G Rotation detection apparatus 2 Housing 3 Shaft (an example of a magnet support body)
4a to 4d magnet 4F ring magnet (an example of a magnet)
5a to 5c Magnetic field detectors 6a to 6c First magnetic member 6Aa to 6Ac First magnetic member 6Ba to 6Bc First magnetic member 6Ca to 6Cc First magnetic member 6Da to 6Dc First magnetic member 6Ea to 6Ec First magnetic member 7a to 7c 2nd magnetic member 7Aa-7Ac 2nd magnetic member 7Ba-7Bc 2nd magnetic member 7Ca-7Cc 2nd magnetic member 7Da-7Dc 2nd magnetic member 7Ea-7Ec 2nd magnetic member 51 Magnetic element 52 Coil 61 1st side plate part 61B 1st side plate part 62 2nd side plate part 62A 2nd side plate part 62B 2nd side plate part 63 3rd side plate part 64 4th side plate part 64D 4th side plate part 65 1st flat plate part 67 2nd flat plate part 71 1st side plate part 71B First side plate portion 72 Second side plate portion 72A Second side plate portion 72B Second side plate portion 73 Third side plate portion 74 Fourth side plate portion 74D Fourth side plate portion 75 First Flat plate portion 77 Second flat plate portion 200 Motor electromagnetic portion M1, M2 Motor R1 to R4 Rotation locus circle SH Motor shaft

Claims (9)

A motor equipped with a rotation detection device,
A motor shaft;
A motor electromagnetic unit for rotating the motor shaft,
The rotation detection device includes:
A housing;
A magnet support that is rotatably supported by the housing, is connected to the motor shaft, and has a magnet fixed thereto;
It has a magnetic element and a coil that generate a large Barkhausen effect, and is fixed to the housing so that its length direction is parallel to the tangential direction of the rotation locus circle of the magnet and can be opposed to the magnet in the radial direction of the rotation locus circle. And a magnetic field detector for detecting the magnetic field of the magnet. The rotation detection device includes:
A first magnetic member fixed to the housing and covering at least a portion facing the magnet on one side in the length direction of the magnetic field detection unit;
A second magnetic member fixed to the housing and covering at least a portion facing the magnet on the other side in the length direction of the magnetic field detection unit,
The first magnetic member and the second magnetic member are:
The motor according to claim 1, wherein the motor is disposed through a gap at a central portion in the length direction of the magnetic field detection unit. The magnet, the first magnetic member, the second magnetic member, and the magnetic field detector are
3. The motor according to claim 2, wherein the magnet, the first magnetic member, the second magnetic member, and the magnetic field detection unit are arranged in this order from the inner side to the outer side in the radial direction. The first magnetic member and the second magnetic member are
A first side plate portion, one end of which is located in the vicinity of the central portion of the magnetic field detection unit, and extends so as to face the magnet in the radial direction;
One end is connected to the first side plate portion, and the other end has a second side plate portion extending so as to protrude outward in the length direction from the length direction end portion of the magnetic field detection portion. The motor according to claim 3. The second side plate portion is
The motor according to claim 4, wherein the motor has a tapered shape toward the other end side. The first magnetic member and the second magnetic member are
A third side plate extending along the width direction of the magnetic field detection unit on the outer side in the length direction from the end of the magnetic field detection unit; and the magnetic field detection on the radially outer side of the magnetic field detection unit. The motor according to claim 4, further comprising at least one of a fourth side plate portion extending along a length direction of the portion. The first magnetic member and the second magnetic member are
It has at least one of the 1st flat plate part which covers the rotation-axis direction one side of the said magnetic field detection part in the rotation-axis direction of the said magnet support body, and the 2nd flat plate part which covers the rotation-axis direction other side of the said magnetic field detection part. The motor according to claim 4 or 6, characterized by the above. There are three magnetic field detectors,
Arranged around the magnet support so as to have a triangular shape when viewed from the direction of the rotation axis,
Three sets of the first magnetic member and the second magnetic member corresponding to the three magnetic field detectors are:
8. The motor according to claim 4, wherein each of the first side plate portions is arranged so as to have a hexagonal shape when viewed from the direction of the rotation axis. The magnet support is
A cylindrical shaft,
The magnet
The motor according to any one of claims 1 to 8, wherein the motor is a ring magnet fixed to an outer periphery of the shaft.

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