JP7111120B2 - Yoke member for torque detector, torque detector, steering device - Google Patents

Description

TECHNICAL FIELD The present invention relates to a yoke member for a torque detection device, a torque detection device, and a steering device used in the torque detection device.

Conventionally, a torque detection device has been proposed in which a change in magnetic flux caused by relative rotation between a multipolar magnet and a yoke member is detected by a magnetic sensor, and the torque applied to the torsion bar is detected based on the detection signal of the magnetic sensor. (See Patent Document 1, for example).

Specifically, the multipole magnet is formed in a cylindrical shape, and N poles and S poles are alternately arranged in the circumferential direction of the multipole magnet. The yoke member has a pair of yoke portions, each of which has a ring plate portion and a tooth portion formed on the inner edge side of the ring plate portion. The yoke member is configured by arranging the yoke portions facing each other so that the tooth portions formed on the yoke portions are arranged alternately. The multipolar magnet and the yoke member are arranged so that the central axis of the multipolar magnet and the central axis of the yoke member (that is, the central axis of the ring plate portion) are aligned.

Japanese Patent No. 5183036

However, when constructing a torque detection device, the central axis of the multipolar magnet and the central axis of the yoke member may deviate from each other due to manufacturing errors during assembly or the like. In this case, a magnetic pole is generated in each yoke portion by generating a flow of magnetic flux. For this reason, if the central axis of the multipolar magnet and the central axis of the yoke member are misaligned, there is a possibility that the torque detection accuracy will be degraded.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a yoke member for a torque detection device, a torque detection device, and a steering device that can suppress deterioration in detection accuracy when a torque detection device is constructed.

In claim 1 for achieving the above object, there is provided a yoke member for a torque detection device in which a pair of first yoke portion (310) and second yoke portion (320) are arranged to face each other, the yoke member having a ring shape. A first ring plate portion (311) and a plurality of first tooth portions (312) arranged at equal intervals on the inner edge portion side of the first ring plate portion and projecting in a direction normal to the surface direction of the first ring plate portion. and a second ring-shaped plate portion (321), which are arranged at equal intervals on the inner edge portion side of the second ring plate portion, and the normal to the surface direction of the second ring plate portion a second yoke portion having a plurality of directionally projecting second teeth (322). The first yoke portion and the second yoke portion are arranged alternately in the circumferential direction of the first ring plate portion so that the first yoke portion and the second yoke portion are arranged alternately. The first yoke portion is arranged so that a predetermined interval is maintained therebetween, and the first yoke portion has a maximum width (L1 ) is narrower than the minimum width (L2) of the narrowest portion of the width between the inner edge side and the outer edge side in the first ring plate portion, and the second yoke portion is arranged in the arrangement direction , the maximum width (L1) of the longest portion of the second tooth portion is greater than the minimum width (L2) of the narrowest portion of the width between the inner edge portion side and the outer edge portion side of the second ring plate portion narrowed.

According to this, in the first and second yoke portions, the maximum widths of the first and second tooth portions are narrower than the minimum widths of the first and second ring plate portions. For this reason, when a torque detector including a multipolar magnet and a yoke member for a torque detector is configured, even if the central axis of the multipolar magnet and the central axis of the yoke member are deviated, the multipolar magnet will still produce the first and second yokes. The magnetic flux induced to the two teeth can be reduced, and the magnetic flux induced from the first and second teeth to the first and second ring plate portions can be reduced. Therefore, it is possible to reduce the strength of the magnetic poles generated in the first and second ring plate portions, thereby suppressing deterioration in detection accuracy.

Further, in claim 5, the yoke member for a torque detecting device in which a pair of the first yoke portion (310) and the second yoke portion (320) are arranged to face each other, the ring-shaped first ring plate portion (311), and a plurality of first tooth portions (312) arranged at equal intervals on the inner edge side of the first ring plate portion and protruding in the direction normal to the surface direction of the first ring plate portion. 1 yoke portion, a ring-shaped second ring plate portion (321), and a plurality of projections arranged at equal intervals on the inner edge portion side of the second ring plate portion and protruding in the direction normal to the surface direction of the second ring plate portion a second yoke portion having a second tooth (322) of . The first yoke portion and the second yoke portion are arranged alternately in the circumferential direction of the first ring plate portion so that the first yoke portion and the second yoke portion are arranged alternately. The first yoke portion is formed with reducing portions (311f, 312b) for reducing the magnetic flux flowing from the first tooth portion to the first ring plate portion, and The second yoke portion is formed with reducing portions (321f, 322b) that reduce the magnetic flux flowing from the second tooth portion to the second ring plate portion.

According to this, the first and second yoke portions are formed with reducing portions for reducing the magnetic flux flowing from the first and second tooth portions to the first and second ring plate portions. Therefore, when a torque detector including a multipolar magnet and a yoke member for a torque detector is constructed, even if the central axis of the multipolar magnet and the central axis of the yoke member deviate, Magnetic flux induced in the first and second ring plate portions can be reduced. Therefore, it is possible to reduce the strength of the magnetic poles generated in the first and second ring plate portions, thereby suppressing deterioration in detection accuracy.

In claim 12, the torsion bar (13) that coaxially connects the first shaft (11) and the second shaft (12) on the rotation center axis (C) is provided with a first rotation centered on the rotation center axis (C). A torque detection device configured to output a detection signal corresponding to torsional torque generated due to relative rotation between a shaft and a second shaft, wherein magnetic poles alternate in a circumferential direction surrounding a central axis of rotation. A multipolar magnet (20) configured to be inverted and arranged coaxially with the torsion bar so as to rotate about the central axis of rotation with relative rotation; According to the magnetic flux generated between the yoke member according to any one of claims 1 to 11 arranged so that (C30) coincides with the rotation center axis, and the first yoke portion and the second yoke portion a magnetic detecting element (70) for outputting a detection signal, and magnetic flux guiding members (81, 82) for guiding the magnetic flux generated between the first yoke portion and the second yoke portion to the magnetic detecting element. there is

As described above, by applying the yoke member to a torque detection device having a magnetic detection element and a magnetic flux guide member, it is possible to effectively suppress deterioration in detection accuracy.

Further, according to claim 16, there is provided a steering device provided in a vehicle, wherein the torque detection device according to any one of claims 12 to 15, and a driver's operation based on a detection signal detected by the torque detection device. and a motor (6) for outputting driving force for assisting the operation of the steering section (5).

Thus, by applying the torque detection device to a steering device having a steering portion, a motor, etc., it is possible to effectively suppress deterioration in detection accuracy.

It should be noted that the reference numerals in parentheses attached to each component etc. indicate an example of the correspondence relationship between the component etc. and specific components etc. described in the embodiments described later.

1 is a schematic configuration diagram of an electric power steering device equipped with a torque detection device according to a first embodiment; FIG. FIG. 2 is an exploded perspective view of the torque detection device shown in FIG. 1; 3 is an enlarged perspective view of a multipolar magnet and a yoke member in the assembled state of the torque detection device shown in FIG. 2; FIG. It is a perspective view of a yoke member. 4B is a cross-sectional view of the yoke member taken along line IVB-IVB in FIG. 4A; FIG. It is a top view of a 1st, 2nd yoke part. FIG. 4 is a side view showing a relative rotation state of the multipolar magnet, first yoke portion, and second yoke portion shown in FIG. 3; FIG. 4 is a side view showing a relative rotation state of the multipolar magnet, first yoke portion, and second yoke portion shown in FIG. 3; FIG. 4 is a side view showing a relative rotation state of the multipolar magnet, first yoke portion, and second yoke portion shown in FIG. 3; It is a front view of a magnetic sensor. FIG. 7 is a cross-sectional view taken along line VII-VII in FIG. 6; It is a schematic diagram which attached the magnetic sensor to the accommodation wall, and comprised the torque detection apparatus. FIG. 5 is a plan view for explaining magnetic poles generated in the yoke member when the central axis of the multipolar magnet and the central axis of the yoke member are misaligned; FIG. 5 is a perspective view for explaining magnetic poles generated in the yoke member when the central axis of the multipolar magnet and the central axis of the yoke member are misaligned; It is a figure which shows the relationship between a detection signal and a rotation angle. It is a figure which shows the relationship between magnetic field strength and the magnetic flux density of a 1st, 2nd ring-plate part. FIG. 5 is a diagram showing the relationship between the magnetic flux densities of the first and second ring plate portions and the output fluctuation amplitude at maximum eccentricity of the multipole magnet; FIG. 10 is a plan view for explaining magnetic poles generated in the yoke member when the multipolar magnet has 24 poles and the central axis of the multipolar magnet and the central axis of the yoke member are misaligned; FIG. 10 is a plan view of first and second yoke portions in the second embodiment; FIG. 11 is an exploded perspective view of a torque detection device according to a third embodiment; It is a top view of the 1st, 2nd yoke part in 4th Embodiment. FIG. 11 is a plan view of first and second yoke portions in a modification of the fourth embodiment; It is a perspective view of the 1st, 2nd yoke part in 5th Embodiment. It is a perspective view of the 1st, 2nd yoke part in 6th Embodiment. FIG. 21 is a perspective view of first and second yoke portions in a modified example of the sixth embodiment;

An embodiment of the present invention will be described below with reference to the drawings. In addition, in each of the following embodiments, portions that are the same or equivalent to each other will be described with the same reference numerals.

(First embodiment)
A first embodiment will be described with reference to the drawings. In this embodiment, an example in which a torque detection device is configured using a yoke member for a torque detection device and an electric power steering device is configured using the torque detection device will be described. In this embodiment, a so-called column-type electric power steering device mounted on a vehicle will be described.

The electric power steering device 1 includes a steering wheel 5, an electric motor 6, a steering gear mechanism 7, a link mechanism 8, and a torque detection device 10, as shown in FIG. The electric power steering device 1 drives the electric motor 6 according to the operating state of the steering wheel 5 and transmits the driving force of the electric motor 6 to the steering gear mechanism 7 . Thereby, the electric power steering device 1 assists the steering force for changing the direction of the wheels T via the link mechanism 8 . In addition, in this embodiment, the steering wheel 5 corresponds to a steering unit.

The torque detection device 10 is provided between the steering wheel 5 and the steering gear mechanism 7 so as to output a detection signal (for example, voltage) according to the operating state of the steering wheel 5 . Specifically, the torque detection device 10 is arranged at the connecting portion between the first shaft 11 and the second shaft 12 . The first shaft 11 is connected to the steering wheel 5 via a connecting mechanism (not shown) so as to rotate together with the steering wheel 5 . The second shaft 12 is connected to the steering gear mechanism 7 via a connection mechanism (not shown).

The first shaft 11 and the second shaft 12 are coaxially connected on the rotation center axis C via the torsion bar 13 . The torque detection device 10 outputs a detection signal corresponding to the torsion torque generated in the torsion bar 13 due to the relative rotation between the first shaft 11 and the second shaft 12 about the rotation center axis C. is configured to The torsion bar 13 is fixed to the first shaft 11 and the second shaft 12 with a fixing pin 14, as shown in FIG. 2, which will be described later.

Next, the basic configuration of the torque detection device 10 according to this embodiment will be described with reference to FIG. For convenience of explanation, a right-handed XYZ orthogonal coordinate system in which the Z-axis is parallel to the rotation center axis C is appropriately set in each of the following figures. At this time, the direction parallel to the Z-axis is also referred to as the axial direction. In many cases, the center axis of rotation C is not parallel to the vehicle height direction.

The torque detection device 10 has a multipolar magnet 20 . The multipolar magnet 20 is arranged coaxially with the torsion bar 13 so as to rotate about the rotation center axis C as the first shaft 11 and the second shaft 12 rotate relative to each other. Specifically, the multipolar magnet 20 is cylindrical and fixed to the lower end of the first shaft 11 . The multipolar magnet 20 is configured such that the magnetic poles are alternately reversed in the circumferential direction surrounding the central axis C of rotation.

Note that the circumferential direction is typically the circumferential direction of a circle formed in the XY plane around the intersection of the rotation center axis C and the XY plane. Also, in the present embodiment, the multipolar magnet 20 has eight north and south poles, and a total of 16 poles arranged at intervals of 22.5°.

On the radially outer side of the multipole magnet 20, as shown in FIGS. 2 and 3, a substantially cylindrical shape having a first yoke portion 310 and a second yoke portion 320 arranged to face the multipole magnet 20 yoke member 30 is arranged. The configuration of the yoke member 30 of this embodiment will be specifically described below with reference to FIGS. 2, 3, and 4A to 4C. 2 and 3, a holding member 340, which will be described later, and the like in the yoke member 30 are omitted. FIG. 4C is a plan view seen from one surface 311a of the first ring plate portion 311 in the first yoke portion 310 described later and one surface 321a of the second ring plate portion 321 in the second yoke portion 320 described later. .

The yoke member 30 has a pair of first yoke portion 310 and second yoke portion 320, a fixing collar 330, and a holding member 340 that integrally holds them.

The first yoke portion 310 is made of a soft magnetic material and has a first ring plate portion 311 and a plurality of first tooth portions 312 . Specifically, the first ring plate portion 311 is formed in a flat ring shape having one surface 311a and the other surface 311b. That is, the first ring plate portion 311 has a circular opening in the center. The plurality of first tooth portions 312 protrude toward the one surface 311a of the first ring plate portion 311 on the inner edge portion side of the first ring plate portion 311 and are arranged at regular intervals in the circumferential direction. In the present embodiment, the inner diameter and the outer diameter of the first ring plate portion 311 are substantially perfect circles. Further, the surface of the first tooth portion 312 on the opening side is also referred to as an inner surface 312a of the first tooth portion 312 hereinafter. Further, in this embodiment, the first tooth portion 312 has a tapered shape in which the width becomes narrower from the root portion side to the tip portion side.

Similarly, the second yoke portion 320 is made of soft magnetic material and has a second ring plate portion 321 and a plurality of second tooth portions 322 . Specifically, the second ring plate portion 321 is formed in a flat ring shape having one surface 321a and the other surface 321b. That is, the second ring plate portion 321 has a circular opening in the center. The plurality of second tooth portions 322 protrude toward the one surface 321a of the second ring plate portion 321 on the inner edge portion side of the second ring plate portion 321 and are arranged at regular intervals in the circumferential direction. In addition, in this embodiment, the inner diameter and the outer diameter of the second ring plate portion 321 are substantially circular. In the following, the surface of the second tooth portion 322 on the side of the opening is also referred to as an inner surface 322a of the second tooth portion 322 . Further, in this embodiment, the second tooth portion 322 has a tapered shape in which the width becomes narrower from the root portion side toward the tip portion side.

The first yoke portion 310 and the second yoke portion 320 are arranged so that the surfaces 311a and 321a face each other. Specifically, the first yoke portion 310 and the second yoke portion 320 are arranged to face each other with a predetermined interval while the first tooth portions 312 and the second tooth portions 322 are alternately arranged in the circumferential direction. It is That is, the first yoke portion 310 and the second yoke portion 320 are arranged such that the first ring plate portion 311 and the second ring plate portion 321 face each other along the axial direction. In other words, the first ring plate portion 311 and the second ring plate portion 321 are arranged so as to overlap when viewed from the axial direction.

Further, in the present embodiment, as shown in FIG. 4C, the first yoke portion 310 has a maximum width L1 of the first tooth portion 312 in the normal direction to the one surface 311a (hereinafter also simply referred to as the normal direction). is narrower than the minimum width L2 of the first ring plate portion 311 . Similarly, in the second yoke portion 320, the maximum width L1 of the second tooth portion 322 is greater than the minimum width L2 of the second ring plate portion 321 in the direction normal to the one surface 321a (hereinafter also simply referred to as the normal direction). are also narrowed.

In this embodiment, the maximum width L1 of the first and second tooth portions 312 and 322 is equal to Width of the root portion at 312,322. In other words, the maximum width L1 of the first and second tooth portions 312 and 322 is the width of the portion connected to the first and second ring plate portions 311 and 321 . The minimum width L2 of the first and second ring plate portions 311 and 321 is the length of the shortest portion of the lengths between the inner and outer edge portions of the first and second ring plate portions 311 and 321. It is the length of the part where the difference between the inner diameter and the outer diameter is the shortest. In this embodiment, the inner and outer diameters of the first and second ring plate portions 311 and 321 are substantially circular. Therefore, the minimum width L2 of the first and second ring plate portions 311 and 321 is, for example, between the adjacent first and second tooth portions 312 and 322 of the first and second ring plate portions 311 and 321. is the width of the part located in the center of the

As will be described later, the fixing collar 330 is a ring-shaped member that is fixed to the second shaft 12 and is arranged on the side opposite to the first yoke portion 310 with the second yoke portion 320 interposed therebetween.

The holding member 340 is a member that integrally holds the first yoke portion 310, the second yoke portion 320, and the fixing collar 330, and is made of thermoplastic resin or the like. Specifically, the holding member 340 has a substantially cylindrical shape having an inner peripheral surface 340a and an outer peripheral surface 340b. formed to be exposed. Further, the holding member 340 is formed with a groove portion 341 that exposes the one surface 311a of the first ring plate portion 311 and the one surface 321a of the second ring plate portion 321 on the outer peripheral surface 340b. That is, the holding member 340 has a groove 341 formed in a portion of the outer peripheral surface 340 b that is located between the first ring plate portion 311 and the second ring plate portion 321 .

The above is the configuration of the yoke member 30 in this embodiment. Such a yoke member 30 is connected to a connection (not shown) formed at the upper end portion of the second shaft 12 so that the first yoke portion 310 and the second yoke portion 320 face the multipolar magnet 20 in the radial direction. It is arranged by fixing the fixing collar 330 to the part. Specifically, the yoke member 30 is arranged so that the central axis of the multipolar magnet 20 and the central axis of the yoke member 30 are aligned. In addition, the yoke member 30 is arranged so that the first yoke portion 310 surrounds one end portion (that is, upper end portion) of the multipolar magnet 20 in the axial direction, and the second yoke portion 320 is arranged in the axial direction of the multipolar magnet 20. It is arranged so as to surround the other end (that is, the lower end). Therefore, the first yoke portion 310 and the second yoke portion 320 are formed with a circular opening centered on the rotation center axis C, and the first tooth portion 312 or the second tooth portion 322 is formed along the rotation center axis C. It can be said that it is configured to have The central axis of the yoke member 30 can also be said to be an axis passing through the centers of the first and second ring plate portions 311 and 321 .

The yoke member 30 is rotatable relative to the multipolar magnet 20 by integrally rotating with the second shaft 12 . Thereby, the first yoke portion 310 and the second yoke portion 320 form a magnetic circuit within the magnetic field generated by the multipolar magnet 20 . In this embodiment, the axial direction corresponds to the direction in which the first yoke portion 310 and the second yoke portion 320 are arranged.

Here, in the assembled state where no torsional torque acts on the torsion bar 13, the multipolar magnet 20, the first yoke portion 310, and the second yoke portion 320 are shown in FIGS. 3 and 5A. , the phases are aligned in a neutral state in the circumferential direction. The neutral state is a state in which the center positions in the circumferential direction of all the first tooth portions 312 and the second tooth portions 322 coincide with the boundaries between the N poles and the S poles. Here, it is assumed that the central axis of the multipolar magnet 20 and the central axis of the yoke member 30 are aligned.

When torsion torque is generated in the torsion bar 13 due to relative rotation between the first and second shafts 11 and 12, the first yoke portion 310 and the second yoke portion 320 are shown in FIGS. 5B and 5C. As shown, the phase shifts from the neutral state. Thereby, first yoke portion 310 and second yoke portion 320 generate magnetic flux density B corresponding to the amount of phase shift.

2, the torque detection device 10 has the magnetic detection element 70 and the first and second magnetic flux guide members 81 and 82 arranged close to the first yoke portion 310 and the second yoke portion 320. It is configured by arranging a magnetic sensor 40 having. The magnetic sensor 40 is configured to output a detection signal corresponding to the magnetic flux generated by the first and second yoke portions 310 and 320, that is, a detection signal corresponding to the torsional torque generated in the torsion bar 13. . The configuration of the magnetic sensor 40 of this embodiment will be described below with reference to FIGS. 6 and 7. FIG. The right-handed XYZ orthogonal coordinate system in FIGS. 6 and 7 corresponds to the right-handed XYZ orthogonal coordinate system in FIG. Also, FIG. 6 omits a covering material 90 to be described later.

As shown in FIGS. 6 and 7, the magnetic sensor 40 of this embodiment has a sensor housing 50, a circuit board 60, a magnetic detection element 70, and first and second magnetic flux guide members 81 and 82. It is configured.

The sensor housing 50 includes a columnar main portion 51 extending in the y-axis direction and a flange portion 52 . In addition, below, in the sensor housing 50 and the main part 51, the paper surface lower side in FIG. 6 is also called one end part side, and the paper surface upper side in FIG. 6 is also called the other end part side. 8, in the sensor housing 50 and the main portion 51, the ends located on the first and second yoke portions 310 and 320 are also referred to as one end, and the end opposite to the one end is referred to as the one end. is also called the other end side.

In this embodiment, the main portion 51 is formed by molding an insulating synthetic resin. A housing recess 53 is formed on one end side of the main portion 51 . The accommodation recess 53 accommodates the circuit board 60 and has a shape corresponding to the outer shape of the circuit board 60 . In this embodiment, as will be described later, since the circuit board 60 has a planar rectangular shape, the accommodation recess 53 also has a planar rectangular shape. A convex portion 54 is formed on the side surface of the accommodation concave portion 53 .

The other end of the main portion 51 serves as a connector portion 55 electrically connected to an external device, and the connector portion 55 has an opening 55a. Note that the external device is, for example, an ECU (abbreviation of Electronic Control Unit) or the like.

Further, a plurality of terminals 56 are integrated with the main portion 51 by insert molding or the like. Specifically, each terminal 56 is provided on the main portion 51 such that one end thereof is exposed from the housing recess 53 and the other end thereof is exposed from the opening 55a. One end of the terminal 56 exposed from the accommodation recess 53 is inserted through an insertion hole 61 formed in a circuit board 60 to be described later, and electrically and mechanically connected to the circuit board 60 . The other end exposed from the opening 55a of the terminal 56 is electrically connected to an external device.

The flange portion 52 is made of a metal material having higher rigidity than the main portion 51, and has a frame shape with a through hole 57 formed substantially in the center. As the metal material forming the flange portion 52, iron, an alloy containing iron as a main component, aluminum, an alloy containing aluminum as a main component, or the like is used. The flange portion 52 is provided on the main portion 51 so that the main portion 51 extends through the through hole 57 . In this embodiment, the flange portion 52 is provided closer to the other end than the portion of the main portion 51 where the accommodating recessed portion 53 is formed. Note that the flange portion 52 is integrated with the main portion 51 by, for example, insert molding. Further, the flange portion 52 is fixed to the main portion 51 with an adhesive or the like after the main portion 51 is inserted into the through hole 57, for example.

A fixing hole 58 is formed through the outer edge of the flange portion 52 along the y-axis direction.

The circuit board 60 has a planar rectangular shape with one surface 60a and the other surface 60b, and an insertion hole 61 into which one end of the terminal 56 is inserted is formed. Further, the circuit board 60 is formed with recesses 62 corresponding to the protrusions 54 formed in the accommodation recesses 53 . Further, the circuit board 60 is formed with an opening 63 into which an extending portion 82b of the second magnetic flux guide member 82, which will be described later, is inserted.

The magnetic detection element 70 outputs a detection signal corresponding to the magnetic flux of the magnetic circuit formed by the first yoke portion 310 and the second yoke portion 320 . In this embodiment, two magnetic detection elements 70 are arranged along the x-axis direction on the one surface 60a side of the circuit board 60 . In this embodiment, by providing two magnetic detection elements 70 as described above, magnetic field detection can be continued even if one of them becomes unusable due to a failure or the like.

Each magnetic detection element 70 is configured by sealing a magnetic sensing element such as a Hall element inside, and includes a main body formed in a substantially rectangular plane shape and a plurality of terminals provided on the main body. have. Each magnetic detection element 70 is mounted on the circuit board 60 so that the main body overlaps the opening 63 when viewed from the direction normal to the surface direction of the circuit board 60 .

The circuit board 60 on which the magnetic detection element 70 is mounted as described above is arranged in the housing recess 53 formed in the main portion 51 . Specifically, the circuit board 60 is arranged such that the other surface 60 b faces the bottom surface of the housing recess 53 and the opening 63 is located on the one end side of the sensor housing 50 . The circuit board 60 is arranged in the housing recess 53 so that the terminal 56 is inserted through the insertion hole 61 while the recess 62 is fitted with the protrusion 54 formed in the housing recess 53 . The circuit board 60 is fixed to the housing recess 53 by being electrically and mechanically connected to the terminals 56 by soldering or the like. It should be noted that the mechanical connection strength between the circuit board 60 and the sensor housing 50 may be improved by heat caulking the convex portion 54 or the like.

The first magnetic flux guide member 81 and the second magnetic flux guide member 82 are made of a soft magnetic material. In this embodiment, as shown in FIG. 2, the first magnetic flux guiding member 81 includes a rectangular strip-shaped main body portion 81a whose longitudinal direction is the x-axis direction, and a bent portion extending in a direction intersecting the longitudinal direction. and an extended portion 81b. Similarly, the second magnetic flux guiding member 82 has a rectangular strip-shaped body portion 82a whose longitudinal direction is the x-axis direction, and an extended portion 82b that is bent while extending in a direction that intersects the longitudinal direction. It is

The extension portions 81 b and 82 b of the first and second magnetic flux guide members 81 and 82 are provided in a number corresponding to the magnetic detection elements 70 . That is, in this embodiment, since two magnetic detection elements 70 are provided, the first and second magnetic flux guide members 81 and 82 are provided with two extension portions 81b and 82b, respectively.

In this embodiment, the main body portion 81a of the first magnetic flux guiding member 81 is fixed to the side surface of the housing recess 53 with an adhesive or the like. Further, the first magnetic flux guiding member 81 is configured so that the end of the extended portion 81b on the side opposite to the body portion 81a side (hereinafter also referred to as the tip portion) faces the body portion of the magnetic detection element 70 while being close to it. is folded into

The main body portion 82a of the second magnetic flux guide member 82 is fixed to the bottom surface of the housing recess 53 via an adhesive or the like so as to face the first magnetic flux guide member 81 in the axial direction. Further, the second magnetic flux guiding member 82 is arranged such that the end of the extended portion 82b on the side opposite to the body portion 82a side (hereinafter also referred to as the tip portion) faces the body portion of the magnetic detection element 70 while being close to the body portion 82a. and the tip is inserted into the opening 63 . That is, the second magnetic flux guide member 82 is arranged in the housing recess 53 so that at least a portion thereof is inserted into the opening 63 .

As a result, the magnetic sensor 40 is configured such that the magnetic detection element 70 is arranged between the first magnetic flux guide member 81 and the second magnetic flux guide member 82 . That is, the magnetic sensor 40 is configured in a state where the second magnetic flux guide member 82 , the magnetic detection element 70 and the first magnetic flux guide member 81 are fixed to the common sensor housing 50 . For this reason, the magnetic sensor 40 of the present embodiment separately includes a member for mounting the magnetic detection element 70 and a member for mounting the first and second magnetic flux guide members 81 and 82, and these are integrated. In comparison, it is possible to suppress the deviation of the positional relationship between the magnetic detection element 70 and the first and second magnetic flux guide members 81 and 82 .

Note that the tip of the extension portion 81b of the first magnetic flux guide member 81 and the tip of the extension portion 82b of the second magnetic flux guide member 82 may be arranged apart from the magnetic detection element 70, or the magnetic detection It may be in contact with the element 70 . Further, the first magnetic flux guide member 81 and the second magnetic flux guide member 82 have main body portions 81a and 82a arranged on one end side of the sensor housing 50, and extending portions 81b and 82b extending from the main body portions 81a and 82a to the sensor housing 50. is arranged to extend toward the other end side of the

A waterproof covering material 90 is arranged in the housing recess 53 to integrally cover and fix the circuit board 60 , the magnetic detecting element 70 , and the first and second magnetic flux guiding members 81 and 82 . As a result, exposure of the circuit board 60 and the like to water is suppressed, and variation in the positional relationship between the magnetic detection element 70 and the first and second magnetic flux guide members 81 and 82 is suppressed. In addition, such a covering material 90 is made of, for example, an epoxy resin.

The above is the configuration of the magnetic sensor 40 in this embodiment. When the torque detection device 10 is configured, the magnetic sensor 40 is arranged with one end portion of the sensor housing 50 directed toward the first yoke portion 310 and the second yoke portion 320 as described above.

Specifically, the multipolar magnet 20 and the yoke member 30 are housed within the housing wall W, as shown in FIG. In order to facilitate understanding, FIG. 8 shows the first yoke portion 310 and the second yoke portion 320 of the yoke member 30, and also shows the first yoke portion 310 and the second yoke portion 320 in a simplified manner. , the N pole, the torsion bar 13, and the first tooth portion 312 are hatched. In this embodiment, the housing wall W is a wall material that constitutes a casing in the electric power steering device 1 shown in FIG. It is formed to cover. A mounting hole W1, which is a through hole, is formed in the housing wall W. As shown in FIG.

The magnetic sensor 40 is fixed to the housing wall W so that one end of the sensor housing 50 is inserted into the housing wall W through the mounting hole W1. Specifically, the magnetic sensor 40 is arranged such that the lower end surface of the flange portion 52 contacts the outer wall surface of the housing wall W around the mounting hole W1 (that is, the upper surface in FIG. 8). The lower end surface of the flange portion 52 is the surface of the sensor housing 50 on the one end side of the flange portion 52 . The magnetic sensor 40 is fixed to the housing wall W by fixing bolts (not shown) to the housing wall W through the fixing holes 58 .

The magnetic sensor 40 is arranged such that the first magnetic flux guide member 81 is magnetically coupled to the first yoke portion 310 and the second magnetic flux guide member 82 is magnetically coupled to the second yoke portion 320 . In the present embodiment, the magnetic sensor 40 has the first magnetic flux guide member 81 facing the first ring plate portion 311 of the first yoke portion 310 and the second magnetic flux guide member 82 facing the second yoke portion 320 in the axial direction. is arranged so as to face the second ring plate portion 321 of the . That is, the magnetic sensor 40 is arranged such that the first magnetic flux guide member 81 and the second magnetic flux guide member 82 are positioned within the groove 341 formed in the yoke member 30 . That is, in this embodiment, the yoke member 30 has grooves 341 formed in the outer peripheral surface 340b so as to arrange the first magnetic flux guide member 81 and the second magnetic flux guide member 82 in this way. In the torque detection device 10, part of the portion between the first ring plate portion 311 of the first yoke portion 310 and the second ring plate portion 321 of the second yoke portion 320 is provided with the first magnetic flux guide member. 81 and the second magnetic flux guide member 82 are arranged.

As a result, when a torsion torque is generated in the torsion bar 13 as described above, a magnetic flux corresponding to the torsion is generated between the first and second yoke portions 310 and 320, and the magnetic flux is induced by the first and second magnetic flux inductions. It is guided to the magnetic sensing element 70 through the members 81 and 82 . Therefore, a detection signal corresponding to the magnetic flux is output from the magnetic detection element 70 .

The above is the configuration of the torque detection device 10 according to the present embodiment. In such a torque detection device 10, it is possible to suppress a decrease in detection accuracy when the central axis of the multipolar magnet 20 and the central axis of the yoke member 30 are misaligned. 9 to 11, the principle capable of suppressing the deterioration of the detection accuracy will be described with the central axis of the multipolar magnet 20 as the central axis C20 and the central axis of the yoke member 30 as the central axis C30. .

9 and 10, the holding member 340 and the like in the yoke member 30 are omitted. 9 and 10, in the first and second yoke portions 310 and 320, the maximum width L1 of the first and second tooth portions 312 and 322 is equal to the minimum width of the first and second ring plate portions 311 and 321. An example of a conventional yoke member 30 that is wider than L2 (hereinafter also simply referred to as conventional yoke member 30) is shown.

First, as shown in FIGS. 9 and 10, when the central axis C20 of the multipolar magnet 20 and the central axis C30 of the yoke member 30 are misaligned, the first ring plate portion 311 and the second ring plate portion 321 , a magnetic flux path (that is, a magnetic flux flow) is generated to form the magnetic poles of the N pole and the S pole. Specifically, the first ring plate portion 311 and the second ring plate portion 321 are bounded by a portion that intersects an imaginary straight line K passing through the central axis C20 of the multipolar magnet 20 and the central axis C30 of the yoke member 30. , an N pole is formed in one region and an S pole is formed in the other region.

The first yoke portion 310 and the second yoke portion 320 are arranged to face each other with the first and second tooth portions 312 and 322 alternately arranged in the circumferential direction. Therefore, the positional relationship between the S pole and the N pole generated in the first ring plate portion 311 and the positional relationship between the S pole and the N pole generated in the second ring plate portion 321 are opposite.

In this case, the detection signal output from the magnetic sensor 40 in the torque detection device 10 is affected by the magnetic poles generated in the first and second ring plate portions 311 and 321 . For example, when the multipolar magnet 20 and the yoke member 30 rotate simultaneously, it is ideal that the detection signal output from the magnetic sensor 40 is constant. When a magnetic pole is generated at 100.degree. C., as shown in FIG. 11, an output fluctuation (that is, whirling) with a period of 360 degrees is generated. It should be noted that the simultaneous rotation of the multipolar magnet 20 and the yoke member 30 can also be said to be rotation in a state in which the relative positions of the multipolar magnet 20 and the yoke member 30 do not change.

Therefore, when the central axis C20 of the multipolar magnet 20 and the central axis C30 of the yoke member 30 are misaligned, even when detecting the torsion torque of the torsion bar 13, the detection signal output from the magnetic sensor 40 is The output fluctuation shown in FIG. 11 is taken into account. Therefore, when the central axis C20 of the multipolar magnet 20 and the central axis C30 of the yoke member 30 are misaligned, the magnetic poles generated in the first and second ring plate portions 311 and 321 degrade the detection accuracy.

On the other hand, in the present embodiment, as described above, the first and second yoke portions 310 and 320 have the maximum width L1 of the first and second tooth portions 312 and 322 equal to that of the first and second ring plate portions 311 . , 321 is narrower than the minimum width L2. Therefore, the strength of the magnetic poles generated in the first and second ring plate portions 311 and 321 can be reduced.

That is, when the central axis C20 of the multipolar magnet 20 and the central axis C30 of the yoke member 30 are deviated from each other as described above, the path of the magnetic flux is changed from the first and second tooth portions 312 and 322 to the first and second rings. It becomes the path|route which flows to the board part 311,321. For this reason, by making the maximum width L1 of the first and second tooth portions 312 and 322 narrower than the minimum width L2 of the first and second ring plate portions 311 and 321, the multipolar magnet 20 can reach the first and second tooth portions 312 and 322. The magnetic flux induced to the tooth portions 312 and 322 can be reduced, and the magnetic flux induced from the first and second tooth portions 312 and 322 to the first and second ring plate portions 311 and 321 can be reduced. Therefore, the strength of the magnetic poles generated in the first and second ring plate portions 311 and 321 can be reduced. In this embodiment, by making the maximum width L1 narrower than the minimum width L2 in this way, the first and second tooth portions 312 and 322 are guided to the first and second ring plate portions 311 and 321. It reduces the magnetic flux. Therefore, by making the maximum width L1 narrower than the minimum width L2, it can be said that a reducing portion for reducing the magnetic flux density of the magnetic flux flowing through the first and second ring plate portions 311 and 321 is formed.

As a result, when the multipolar magnet 20 and the yoke member 30 rotate at the same time, the detection signal output from the magnetic sensor 40 according to the present embodiment is different from that of the conventional yoke member 30 as shown in FIG. By comparison, the output fluctuation becomes smaller. Therefore, in the torque detection device 10 of the present embodiment, it is possible to suppress deterioration in detection accuracy.

Further, when the central axis C20 of the multipolar magnet 20 and the central axis C30 of the yoke member 30 are misaligned, for example, in the first yoke portion 310, the first ring plate portion 311 of the N-pole portions, the area A near the second tooth portion 322 near the imaginary straight line K tends to have the highest magnetic flux density. Similarly, although not shown, in the second yoke portion 320, the magnetic flux density tends to be highest in the vicinity of the first tooth portion 312 near the imaginary straight line K among the portions of the second ring plate portion 321 that serve as the N pole. .

Then, as shown in FIG. 12, when the amount of displacement (that is, the amount of eccentricity) of the multipolar magnet 20 increases and the magnetic field strength increases, the magnetic flux densities of the first and second ring plate portions 311 and 321 gradually increase. growing. In this case, according to studies by the present inventors, as shown in FIG. 13, when the central axis C20 of the multipolar magnet 20 and the central axis C30 of the yoke member 30 are most deviated (that is, at maximum eccentricity) , if the maximum density of the magnetic flux generated in the first and second ring plate portions 311 and 321 is 50% or less of the saturation magnetic flux density of the first and second ring plate portions 311 and 321, the output fluctuation is greatly reduced. It is confirmed that it can be suppressed. That is, it is possible to greatly suppress the deterioration of the detection accuracy. Therefore, in the first and second yoke portions 310 and 320, the maximum density of the magnetic flux generated in the first and second ring plate portions 311 and 321 at the maximum eccentricity of the multipolar magnet 20 is It is preferable that the maximum width L1 and the minimum width L2 are adjusted so that the saturation magnetic flux density of the ring plate portions 311 and 321 is 50% or less.

As described above, in the yoke member 30 of the present embodiment, the maximum width L1 of the first and second tooth portions 312 and 322 is narrower than the minimum width L2 of the first and second ring plate portions 311 and 321. ing. Therefore, the magnetic flux induced from the multipolar magnet 20 to the first and second tooth portions 312 and 322 can be reduced, and the magnetic flux from the first and second tooth portions 312 and 322 to the first and second ring plate portions 311 and 321 can be reduced. Induced magnetic flux can be reduced. Therefore, the strength of the magnetic poles generated in the first and second ring plate portions 311 and 321 can be reduced, and when the torque detection device 10 is constructed, the central axis C20 of the multipolar magnet 20 and the central axis C30 of the yoke member 30 Even if there is a deviation, it is possible to suppress a decrease in detection accuracy.

In particular, in the torque detection device 10 of the present embodiment, part of the portion between the first ring plate portion 311 of the first yoke portion 310 and the second ring plate portion 321 of the second yoke portion 320 has the first ring plate portion. , second magnetic flux guide members 81 and 82 are arranged. In other words, the torque detection device 10 of the present embodiment surrounds the first and second yoke portions 310 and 320, and the first and second yoke portions 310 and 320 are arranged in the radial direction of the first and second yoke portions 310 and 320. The first and second magnetic flux guide members 81 and 82 are downsized compared to the configuration in which the ring-shaped magnetic flux guide members are arranged so as to face each other. Therefore, while surrounding the first and second yoke portions 310 and 320, the magnetic flux is formed into a ring shape facing the first and second yoke portions 310 and 320 in the radial direction of the first and second yoke portions 310 and 320. In the torque detection device 10 of the present embodiment, the opposing areas between the first and second yoke portions 310 and 320 and the first and second magnetic flux guide members 81 and 82 are smaller than in the configuration in which the guide members are arranged. Therefore, the influence of deviation of the central axes C20 and C30 tends to increase. Therefore, as described above, by making the maximum width L1 of the first and second tooth portions 312 and 322 narrower than the minimum width L2 of the first and second ring plate portions 311 and 321, torque detection in this embodiment The device 10 can effectively suppress the deterioration of the detection accuracy.

As described above, when the multipolar magnet 20 is at its maximum eccentricity, the maximum density of the magnetic flux generated in the first and second ring plate portions 311 and 321 reaches the saturation point of the first and second ring plate portions 311 and 321. Output fluctuations can be greatly suppressed by first and second yoke portions 310 and 320 having a maximum width L1 and a minimum width L2 adjusted to be 50% or less of the magnetic flux density. That is, it is possible to greatly suppress the deterioration of the detection accuracy.

In the first embodiment, the number of poles of the multipolar magnet 20 is 16, but the number of poles of the multipolar magnet 20 can be changed as appropriate. For example, the multipolar magnet 20 may have a total of 24 poles, with 12 north poles and 12 south poles. Also in this case, as shown in FIG. 14, when the central axis C20 of the multipolar magnet 20 and the central axis C30 of the yoke member 30 are misaligned, the first ring plate portion 311 and the second ring plate portion 321 have With the part that intersects an imaginary straight line K that passes through the central axis C20 of the multipolar magnet 20 and the central axis C30 of the yoke member 30 as a boundary, the N pole is formed in one area and the S pole is formed in the other area. . Therefore, the maximum width L1 of the first and second tooth portions 312 and 322 should be narrower than the minimum width L2 of the first and second ring plate portions 311 and 321. Therefore, it is possible to suppress the deterioration of the detection accuracy.

(Second embodiment)
A second embodiment will be described. In this embodiment, the first ring plate portion 311 and the second ring plate portion 321 are formed with ring plate portion side fixing portions. Others are the same as those of the first embodiment, so description thereof is omitted here.

In the present embodiment, as shown in FIG. 15, the first and second ring plate portions 311 and 321 have a positioning ring on the outer edge portion from which a part of the first and second ring plate portions 311 and 321 are removed. Concave portions 311c and 321c are formed. The positioning recesses 311c and 321c are formed by arranging the first and second ring plate portions 311 and 321 in a mold and pouring molten resin into the mold to form the holding member 340. It is for fitting and fixing the first and second ring plate portions 311 and 321 to the mold-side fixing portion formed on the mold. In other words, the positioning recesses 311c and 321c suppress misalignment between the first ring plate portion 311 and the second ring plate portion 321 when the first and second ring plate portions 311 and 321 are arranged in the mold. It is for Further, in this embodiment, the positioning concave portions 311c and 321c correspond to the ring plate portion side fixing portion.

When the positioning recesses 311c and 321c are formed in the first and second ring plate portions 311 and 321 in this manner, the minimum width L2 of the first and second ring plate portions 311 and 321 of the present embodiment is , becomes: That is, as described above, the first and second ring plate portions 311 and 321 have substantially perfect circular inner and outer diameters. Therefore, the minimum width L2 of the first and second ring plate portions 311 and 321 is the width of the portions where the positioning recesses 311c and 321c are formed, and the width of the portions excluding the positioning recesses 311c and 321c. . That is, the minimum width L2 in this embodiment is the length between the inner diameter and the bottom surfaces of the positioning recesses 311c and 321c.

Thus, even when the width of the portions where the positioning recesses 311c and 321c are formed is the minimum width L2, the same effects as in the first embodiment can be obtained. Note that when the inner and outer diameters of the first and second ring plate portions 311 and 321 are not substantially perfect circles and the width of the portions where the positioning recesses 311c and 321c are formed does not become the minimum width, , the minimum width L2 of the first and second ring plate portions 311 and 321 is defined in the same manner as in the first embodiment.

Moreover, although the example in which the positioning recesses 311c and 321c are formed in both the first and second ring plate portions 311 and 321 has been described above, either one of the first and second ring plate portions 311 and 321 is formed. The positioning recess may be formed only on one side. Furthermore, the positioning recesses 311c and 321c as ring plate portion side fixing portions may be formed in the inner edge portions of the first and second ring plate portions 311 and 321 instead of the outer edge portions. It may be formed in an intermediate part between the parts. In addition, when the ring plate portion side fixing portion is formed in the intermediate portion of the first and second ring plate portions 311 and 321, the ring plate portion side fixing portion can also be called a positioning hole portion.

(Third Embodiment)
A third embodiment will be described. In this embodiment, the configurations of the first magnetic flux guide member 81 and the second magnetic flux guide member 82 are changed. Others are the same as those of the first embodiment, so description thereof is omitted here.

In this embodiment, as shown in FIG. 16, the first and second magnetic flux guiding members 81 and 82 are ring-shaped having a diameter larger than the outer diameter of the first and second ring plate portions 311 and 321. ing. The first and second magnetic flux guiding members 81 and 82 are arranged so as to face the first and second ring plate portions 311 and 321 in the radial direction. Note that the first and second magnetic flux guide members 81 and 82 of the present embodiment are provided separately from the sensor housing 50 .

In this manner, the torque detection device 10 in which the first and second magnetic flux guide members 81 and 82 are arranged to face the first and second ring plate portions 311 and 321 in the radial direction can also be used in the first embodiment. You can get the same effect as In the above description, the first and second magnetic flux guide members 81 and 82 are completely ring-shaped, but the first and second magnetic flux guide members 81 and 82 are not perfectly ring-shaped. For example, it may be semicircular. Further, when the first and second magnetic flux guiding members 81 and 82 are arranged so as to face the first and second ring plate portions 311 and 321 in the radial direction, the outer peripheral surface 340b of the holding member 340 The groove portion 341 may not be formed.

(Fourth embodiment)
A fourth embodiment will be described. In this embodiment, convex portions are added to the first ring plate portion 311 and the second ring plate portion 321 in comparison with the second embodiment. Others are the same as those of the second embodiment, so the description is omitted here.

In the present embodiment, as shown in FIG. 17, the first and second ring plate portions 311 and 321 have a positioning ring on the outer edge portion from which a part of the first and second ring plate portions 311 and 321 are removed. Concave portions 311c and 321c are formed. Further, the first and second ring plate portions 311 and 321 are formed with convex portions 311d and 321d for increasing the portions reduced by the positioning concave portions 311c and 321c on the inner edge portions.

Specifically, the protrusions 311d and 321d are formed at portions that intersect an imaginary straight line along the radial direction passing through the positioning recesses 311c and 321c. In this embodiment, the protrusions 311d and 321d are formed so as to protrude toward the inner edge at the inner edge facing the outer edge where the positioning recesses 311c and 321c are formed.

According to this, in the first and second ring plate portions 311 and 321, portions removed by forming the positioning concave portions 311c and 321c are compensated for by the convex portions 311d and 321d. Therefore, in the first and second ring plate portions 311 and 321, it is possible to increase the cross-sectional area perpendicular to the circumferential direction of the portions where the positioning recesses 311c and 321c are formed. That is, the convex portions 311d and 321d function as cross-sectional area increasing portions of the first and second ring plate portions 311 and 321, respectively. Therefore, compared with the second embodiment, the saturation magnetic flux densities of the first and second ring plate portions 311 and 321 can be increased, and the occurrence of output fluctuation can be suppressed.

In FIG. 17, the minimum width L2 is the width of the portions where the positioning recesses 311c and 321c and the projections 311d and 321d are formed. However, the minimum width L2 may be the width of a portion different from the portions where the positioning recesses 311c and 321c and the protrusions 311d and 321d are formed.

(Modified example of the fourth embodiment)
A modification of the fourth embodiment will be described. In the above-described fourth embodiment, as shown in FIG. 18, the first and second ring plate portions 311 and 321 have, in the intermediate portion between the inner edge portion and the outer edge portion, a positioning ring serving as a ring-side fixing portion. Holes 311e and 321e may be formed. In this case, the convex portions 311d and 321d may be formed at portions that intersect with the imaginary straight line along the radial direction passing through the positioning holes 311e and 321e. 18, the positioning holes 311e and 321e are formed between the first and second tooth portions 312 and 322 and the outer edge portions of the first and second ring plate portions 311 and 321, respectively. Protrusions 311d and 321d are formed in the portion. However, when the positioning holes 311e and 321e are formed in portions different from the portions between the first and second tooth portions 312 and 322 and the outer edge portions of the first and second ring plate portions 311 and 321, The protrusions 311 d and 321 d may be formed on inner edges of the first and second ring plate portions 311 and 321 .

(Fifth embodiment)
A fifth embodiment will be described. In contrast to the first embodiment, this embodiment constitutes a reducing portion that reduces the magnetic flux flowing from the first and second tooth portions 312 and 322 to the first and second ring plate portions 311 and 321 . Others are the same as those of the first embodiment, so the description is omitted here.

In this embodiment, the first and second yoke portions 310 and 320 are formed with reduction portions that reduce the magnetic flux density of the magnetic flux flowing through the first and second ring plate portions 311 and 321 . Specifically, as shown in FIG. 19, the first and second ring plate portions 311 and 321 are configured to have auxiliary plate portions 311f and 321f. The auxiliary plate portions 311f and 321f are made of the same material as the first and second yoke portions 310 and 320, and have the same ring plate shape as the first and second ring plate portions 311 and 321. . The thickness t2 of the first and second ring plate portions 311 and 321 is made thicker than the thickness t1 of the first and second tooth portions 312 and 322 .

The thickness t1 of the first and second tooth portions 312 and 322 is the thickness between the inner surfaces 312a and 322a of the first and second tooth portions 312 and 322 and the outer surface opposite to the inner surfaces 312a and 322a. It's about length. Further, in this embodiment, the auxiliary plate portions 311f and 321f are arranged so as to constitute the other surfaces 311b and 321b of the first and second ring plate portions 311 and 321, respectively. However, the auxiliary plate portions 311f and 321f may be arranged so as to form the surfaces 311a and 321a of the first and second ring plate portions 311 and 321, respectively.

In the present embodiment, by configuring the first and second ring plate portions 311 and 321 to have the auxiliary plate portions 311f and 321f, the normal direction of the first and second tooth portions 312 and 322 is smaller than the minimum cross-sectional area S2 of the cross-sectional areas of the first and second ring plate portions 311 and 321 perpendicular to the circumferential direction. In this embodiment, since the first and second tooth portions 312 and 322 are tapered in width from the root portion side to the tip portion side, the maximum cross-sectional area S1 is the same as that of the root portion. area. In this embodiment, the maximum cross-sectional area S1 of the first and second tooth portions 312 and 322 is made smaller than the minimum cross-sectional area S2 of the first and second ring plate portions 311 and 321. This constitutes a reducing section.

Further, in this embodiment, the maximum width L1 and the minimum width L2 are set to 3 to 4 mm based on workability and the like when manufacturing the first and second yoke portions 310 and 320 . Also, the thickness t2 of the first and second ring plate portions 311 and 321 having the auxiliary plate portions 311f and 321f is 0.8 to 1.2 mm. In other words, in the present embodiment, the first and second yoke portions 310 and 320 have the maximum width L1 and the first and second ring plates so that the ratio of the maximum width L1 to the thickness t2 is 2.5 or more. A thickness t2 of the portions 311 and 321 is set. In addition, the first and second yoke portions 310 and 320 have the minimum width L2 and the first and second ring plate portions 311 and 321 so that the ratio of the minimum width L2 to the thickness t2 is 2.5 or more. A thickness t2 is set. The maximum cross-sectional area S1 (that is, the cross-sectional area of the root portion) of the first and second tooth portions 312 and 322 is set to 2.4 mm ² or more. However, as described above, the maximum cross-sectional area S1 of the first and second tooth portions 312 and 322 is made smaller than the minimum cross-sectional area S2 of the first and second ring plate portions 311 and 321 .

In the embodiment described above, the first and second yoke portions 310 and 320 are such that the maximum cross-sectional area S1 of the first and second tooth portions 312 and 322 is the minimum of the first and second ring plate portions 311 and 321. It is made smaller than the cross-sectional area S2. Therefore, compared to the case where the maximum cross-sectional area S1 of the first and second tooth portions 312 and 322 is equal to or larger than the minimum cross-sectional area S2 of the first and second ring plate portions 311 and 321, the multipolar magnet 20 to the first and second tooth portions 312 and 322 can be reduced, and the magnetic flux induced from the first and second tooth portions 312 and 322 to the first and second ring plate portions 311 and 321 can be reduced. can. Therefore, the strength of the magnetic poles generated in the first and second ring plate portions 311 and 321 can be reduced, and when the torque detection device 10 is constructed, the central axis C20 of the multipolar magnet 20 and the central axis C30 of the yoke member 30 Even if there is a deviation, it is possible to suppress a decrease in detection accuracy.

In addition, in this embodiment, the thickness t2 of the first and second ring plate portions 311 and 321 is changed by arranging the auxiliary plate portions 311f and 321f. That is, the minimum cross-sectional areas S2 of the first and second ring plate portions 311 and 321 are changed. Therefore, in the first and second yoke portions 310 and 320, the maximum cross-sectional area S1 of the first and second tooth portions 312 and 322 is larger than the minimum cross-sectional area S2 of the first and second ring plate portions 311 and 321. The maximum width L1 may be longer than the minimum width L2 as long as it becomes smaller.

Also in this embodiment, as in the first embodiment, the maximum density of the magnetic flux generated in the first and second ring plate portions 311 and 321 at the time of maximum eccentricity of the multipolar magnet 20 is The maximum cross-sectional area S1 of the first and second tooth portions 312 and 322 and the minimum Preferably, the cross-sectional area S2 is adjusted.

(Modified example of the fifth embodiment)
A modification of the fifth embodiment will be described. In the fifth embodiment, by reducing the thickness t1 of the first and second tooth portions 312 and 322, the thickness t2 of the first and second ring plate portions 311 and 321 is reduced to the thickness of the first and second tooth portions. It may be made thicker than the thickness t1 of 312 and 322 . Further, in the fifth embodiment, the first and second ring plate portions 311 and 321 may not include the auxiliary plate portions 311f and 321f, and the base material itself may be thickened. In this case, the thickness of the first and second tooth portions 312 and 322 may be increased as long as the relationship of the fifth embodiment is satisfied.

(Sixth embodiment)
A sixth embodiment will be described. In this embodiment, the reduced portions of the first and second yoke portions 310 and 320 are changed from the fifth embodiment. Others are the same as those of the fifth embodiment, so the description is omitted here.

In this embodiment, as shown in FIG. 20, the cross-sectional areas of the first and second tooth portions 312 and 322 perpendicular to the normal direction are reduced. Squeezed portions 312b and 322b are formed to allow the light to flow. In this embodiment, the narrowed portions 312b and 322b of the first and second yoke portions 310 and 320 are connected to the first and second ring plate portions 311 and 321 of the first and second tooth portions 312 and 322. formed at the base of the Note that, in the present embodiment, the constricted portions 312b and 322b correspond to the decreasing portions.

According to this, the first and second tooth portions 312 and 322 of the first and second yoke portions 310 and 320 are formed with constricted portions 312b and 322b. Therefore, the magnetic flux induced from the multipolar magnet 20 to the first and second tooth portions 312 and 322 is reduced compared to the case where the throttle portions 312b and 322b are not formed in the first and second tooth portions 312 and 322. can be reduced, and the magnetic flux induced from the first and second tooth portions 312 and 322 to the first and second ring plate portions 311 and 321 can be reduced. Therefore, effects similar to those of the fifth embodiment can be obtained.

Further, in the present embodiment, the narrowed portions 312b and 322b are formed at the root portions of the first and second tooth portions 312 and 322, respectively. For this reason, for example, compared to the case where the constricted portions 312b and 322b are formed at the tip portions of the first and second tooth portions 312 and 322, the first and second tooth portions 312 and 322 are connected to the first and second tooth portions 312 and 322, respectively. Magnetic flux induced in the two ring plate portions 311 and 321 can be effectively reduced.

Also in this embodiment, as in the first embodiment, the maximum density of the magnetic flux generated in the first and second ring plate portions 311 and 321 at the time of maximum eccentricity of the multipolar magnet 20 is It is preferable that the shape of the narrowed portions 312b and 322b formed in the first and second ring plate portions 311 and 321 is adjusted so that the saturation magnetic flux density of the second ring plate portions 311 and 321 is 50% or less. .

(Modified example of the sixth embodiment)
A modification of the sixth embodiment will be described. First, the first and second yoke portions 310 and 320 are configured to have first and second tooth portions 312 and 322 and first and second ring plate portions 311 and 321. More specifically, As shown in FIG. 21, it also has first and second connecting portions 313 and 323 that connect the first and second tooth portions 312 and 322 and the first and second ring plate portions 311 and 321 . The narrowed portions 312 b and 322 b may be formed in the first and second connecting portions 313 and 323 . That is, the narrowed portions 312b and 322b may be formed between the first and second tooth portions 312 and 322 and the first and second ring plate portions 311 and 321, respectively. Even if the first and second yoke portions 310 and 320 are configured in this manner, the first and second tooth portions 312 are , 322 to the first and second ring plate portions 311 and 321 can be reduced.

Also, although not shown, the constricted portions 312b and 322b formed on the first and second tooth portions 312 and 322 are not the root portions of the first and second tooth portions 312 and 322, but the tip portions thereof. It may be formed in an intermediate portion or the like between the root portion.

(Other embodiments)
The present invention is not limited to the above-described embodiments, and can be appropriately modified within the scope of the claims.

For example, in each of the above-described embodiments, a column-type electric power steering apparatus has been described as an example. However, each of the above embodiments can also be applied to a rack-type electric power steering device.

Moreover, in each of the above embodiments, each direction is set for convenience of explanation of the embodiments. Therefore, in many cases, the rotation center axis C is in a direction that intersects the vehicle height direction.

Furthermore, in each of the above embodiments, the circuit board 60 may not be mounted on the sensor housing 50 and the magnetic detection element 70 may be arranged directly on the sensor housing 50 . Further, in each of the above-described embodiments, the opening 63 may not be formed in the circuit board 60 .

Further, each of the above embodiments may be combined as appropriate. For example, the second embodiment may be combined with the third, fifth, and sixth embodiments, and the ring plate portion side fixing portion may be formed on at least one of the first and second ring plate portions 311 and 321. good. Also, the third embodiment may be combined with the fourth to sixth embodiments to change the configurations of the first and second magnetic flux guiding members 81 and 82. FIG. By combining the fifth embodiment with the sixth embodiment, the maximum cross-sectional area S1 of the first and second tooth portions 312 and 322 is smaller than the minimum cross-sectional area S2 of the first and second ring plate portions 311 and 321. The constricted portions 312b and 322b may be formed while the width is reduced. In addition, combinations of the above embodiments may be combined as appropriate.

30 yoke member 310 first yoke portion 311 first ring plate portion 312 first tooth portion 320 second yoke portion 321 second ring plate portion 322 second tooth portion

Claims (16)

A yoke member for a torque detection device in which a pair of first yoke portion (310) and second yoke portion (320) are arranged to face each other,
A ring-shaped first ring plate portion (311) and a plurality of first ring plate portions arranged at equal intervals on the inner edge portion side of the first ring plate portion and protruding in the direction normal to the surface direction of the first ring plate portion the first yoke portion having a tooth (312);
A ring-shaped second ring plate portion (321) and a plurality of second ring plate portions arranged at equal intervals on the inner edge portion side of the second ring plate portion and protruding in the direction normal to the surface direction of the second ring plate portion a second yoke portion having a tooth portion (322);
The first yoke portion and the second yoke portion are configured such that the first tooth portion and the second tooth portion are alternately arranged in the circumferential direction of the first ring plate portion, and the first yoke portion and the second yoke portion are arranged alternately. It is arranged so that a predetermined distance is maintained between the two yoke portions,
In the first yoke portion, the maximum width (L1) of the longest portion of the first tooth portion in the arrangement direction of the first yoke portion and the second yoke portion is the inner edge portion of the first ring plate portion. narrower than the minimum width (L2) of the narrowest portion of the width between the side and the outer edge side,
In the second yoke portion, the maximum width (L1) of the longest portion of the second tooth portion in the arrangement direction is the width between the inner edge portion side and the outer edge portion side of the second ring plate portion. A yoke member for a torque detection device, which is narrower than the minimum width (L2) of the narrowest portion of the. At least one of the first ring plate portion and the second ring plate portion is formed with a partially removed ring plate portion side fixing portion (311c, 311e, 321c, 321e),
The width between the inner edge portion side and the outer edge portion side of the first ring plate portion and the second ring plate portion is 2. The yoke member for a torque detecting device according to claim 1, wherein the width is the width of the portion excluding the . At least one of the first ring plate portion and the second ring plate portion is formed with a partially removed ring plate portion side fixing portion (311c, 311e, 321c, 321e),
At least one of the first ring plate portion and the second ring plate portion where the ring plate portion side fixing portion is formed has a radial direction passing through a portion where the ring plate portion side fixing portion is formed. 2. The yoke member for a torque detecting device according to claim 1, wherein convex portions (311d, 321) are formed at portions intersecting the imaginary straight line along the . The maximum width of the first tooth portion is the width of the root portion connected to the first ring plate portion,
The yoke member for a torque detecting device according to any one of claims 1 to 3, wherein the maximum width of the second tooth portion is the width of the root portion connected to the second ring plate portion. A yoke member for a torque detection device in which a pair of first yoke portion (310) and second yoke portion (320) are arranged to face each other,
A ring-shaped first ring plate portion (311) and a plurality of first ring plate portions arranged at equal intervals on the inner edge portion side of the first ring plate portion and protruding in the direction normal to the surface direction of the first ring plate portion the first yoke portion having a tooth (312);
A ring-shaped second ring plate portion (321) and a plurality of second ring plate portions arranged at equal intervals on the inner edge portion side of the second ring plate portion and protruding in the direction normal to the surface direction of the second ring plate portion a second yoke portion having a tooth portion (322);
The first yoke portion and the second yoke portion are configured such that the first tooth portion and the second tooth portion are alternately arranged in the circumferential direction of the first ring plate portion, and the first yoke portion and the second yoke portion are arranged alternately. It is arranged so that a predetermined distance is maintained between the two yoke portions,
the first yoke portion is formed with reducing portions (311f, 312b) for reducing the magnetic flux flowing from the first tooth portion to the first ring plate portion;
A yoke member for a torque detecting device, wherein the second yoke portion is formed with reducing portions (321f, 322b) for reducing magnetic flux flowing from the second tooth portion to the second ring plate portion. In the reduced portion of the first yoke portion, the maximum cross-sectional area (S1) in the cross-sectional area of the portion of the first tooth portion perpendicular to the normal direction is the portion perpendicular to the circumferential direction of the first ring plate portion. is made smaller than the minimum cross-sectional area (S2) in the cross-sectional area of
In the reduced portion of the second yoke portion, the maximum cross-sectional area (S1) in the cross-sectional area of the portion of the second tooth portion perpendicular to the normal direction is the portion perpendicular to the circumferential direction of the second ring plate portion. 6. The yoke member for a torque detecting device according to claim 5, wherein the yoke member for a torque detecting device is configured to be smaller than the minimum cross-sectional area (S2) in the cross-sectional area of . The maximum cross-sectional area of the first tooth portion is a root portion of the first tooth portion located on the first ring plate portion side,
7. The yoke member for a torque detecting device according to claim 6, wherein the maximum cross-sectional area of the second tooth portion is a root portion of the second tooth portion located on the second ring plate portion side. The yoke member for a torque detector according to claim 6 or 7, wherein the maximum cross-sectional area of the first tooth portion and the maximum cross-sectional area of the second tooth portion are 2.4 ^mm2 or more. The thickness (t2) of the first ring plate portion is thicker than the thickness (t1) of the first tooth portion,
The yoke member for a torque detecting device according to any one of claims 6 to 8, wherein the thickness (t2) of the second ring plate portion is thicker than the thickness (t1) of the second tooth portion. The reduced portion of the first yoke portion is the narrowed portion (312b) formed in the first tooth portion or the first connecting portion (313) connecting the first tooth portion and the first ring plate portion. is composed of
The reduced portion of the second yoke portion is the narrowed portion (322b) formed in the second tooth portion or the second connecting portion (323) connecting the second tooth portion and the second ring plate portion. 10. The yoke member for a torque detector according to any one of claims 5 to 9. The narrowed portion of the first yoke portion is formed in a root portion of the first tooth portion located on the first ring plate portion side,
11. The yoke member for a torque detecting device according to claim 10, wherein the narrowed portion of the second yoke portion is formed in a root portion of the second tooth portion located on the second ring plate portion side. A torsion bar (13) that coaxially connects a first shaft (11) and a second shaft (12) on a central axis of rotation (C) is provided with the first shaft and the A torque detection device configured to output a detection signal corresponding to torsional torque generated due to relative rotation with a second shaft,
Multipoles arranged coaxially with the torsion bar so that the magnetic poles are alternately reversed in a circumferential direction surrounding the rotation center axis and rotated about the rotation center axis with the relative rotation. a magnet (20);
12. The yoke member according to any one of claims 1 to 11, which is arranged so that the central axis (C30) coincides with the rotation central axis so as to surround the multipolar magnet;
a magnetic detection element (70) for outputting the detection signal corresponding to the magnetic flux generated between the first yoke portion and the second yoke portion;
and a magnetic flux guide member (81, 82) that guides the magnetic flux generated between the first yoke portion and the second yoke portion to the magnetic detection element. 13. The torque detecting device according to claim 12, wherein the magnetic flux guiding member is arranged in a portion of a portion between the first ring plate portion and the second ring plate portion. The magnetic flux guiding member is arranged to have a portion facing the first ring plate portion and the second ring plate portion in a radial direction of the first ring plate portion and the second ring plate portion. Item 13. The torque detection device according to item 12. In the first ring plate portion and the second ring plate portion, when the eccentricity of the multipolar magnet is maximized, the maximum density of the magnetic flux generated in the first ring plate portion and the second ring plate portion is 15. The torque detecting device according to claim 12, wherein the saturation magnetic flux density in said first ring plate portion and said second ring plate portion is 50% or less. A steering device provided in a vehicle,
a torque detection device according to any one of claims 12 to 15;
and a motor (6) for outputting a driving force for assisting the operation of a steering section (5) operated by a passenger based on the detection signal detected by the torque detection device.

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